What is AUTOSAR and How is Crypto Used with it?

AUTOSAR stands for AUTomotive Open System ARchitecture and is a group of companies that set a standardized way for components used in the automotive industry to interface with each other. There are multiple release versions of the AUTOSAR documents and standardizations, but the ones we focus on are those that consume cryptography, and in particular how the AUTOSAR cryptography standards can consume wolfCrypt. The AUTOSAR crypto stack is made up of Crypto Service Manager, Crypto Interface, and Crypto Driver. Where the Crypto Service Manager is the highest level of abstraction and the Crypto Driver is at the lowest level, the driver being either provided by a cryptography implementation done in software or hardware or resident in an automotive HSM. wolfCrypt is callable in all of the above scenarios through the AUTOSAR abstraction API’s. One of the benefits of using AUTOSAR with wolfCrypt is seamless transition between our software encryption, our encryption calling into hardware encryption, or calling into an HSM as you re-use your higher level code in successive projects.

If you have a need for software cryptography operations that conform to the AUTOSAR specifications contact us at facts@wolfSSL.com. You can find some example code from here.

If you have questions about any of the above, please contact us at facts@wolfSSL.com or call us at +1 425 245 8247.

Download wolfSSL Now

Live Webinar: Getting Started with wolfMQTT

Welcome to the third episode of the Getting Started series! Join us for “Getting Started with wolfMQTT” on February 15th at 10 am PT, presented by wolfSSL Senior Software Engineer, Eric. Explore how wolfMQTT, a client implementation of the MQTT protocol written in C for embedded systems, can bolster your IoT security. Eric will guide you from foundational concepts to advanced features, empowering you to effectively utilize the capabilities of wolfMQTT.

In this webinar, you’ll delve into key topics including:

  • The significance of having a dedicated IoT protocol
  • An overview of the MQTT protocol
  • Specifications supported by the wolfMQTT client
  • Understanding the architecture of wolfMQTT
  • Configuration and build processes
  • Real-world wolfMQTT examples
  • Insights into future development plans

Watch the webinar now: Getting Started with wolfMQTT

Don’t miss this opportunity to enhance your understanding of MQTT and strengthen your security infrastructure with wolfMQTT. Watch now!

As always, our webinars will include Q&A sessions throughout the webinar. If you have questions about any of the above, please contact us at facts@wolfSSL.com or call us at +1 425 245 8247.

Download wolfSSL Now

wolfBoot Support for Renesas RZ/N2L

wolfBoot currently support both Renesas RA6M4 and RX72N MCUs. Supporting other Renesas MCUs for wolfBoot should not be difficult. We are considering the addition of Renesas RZ/N2L support for wolfBoot, which will build on our existing support at the wolfSSL and wolfCrypt level for Renesas RZ/N2L.

The Renesas RZ/N2L uses a high-performance Arm Cortex-R52 core to easily add network functionality onto industrial equipment and machines. The RZ/N2L is supported by an open and flexible ecosystem concept – the Flexible Software Package (FSP), built on FreeRTOS – and is expandable to use other RTOS and middleware solutions.

If you are interested in wolfBoot support on the RZ/N2L or have questions about any of the above, please contact us at facts@wolfSSL.com or call us at +1 425 245 8247.

Download wolfSSL Now

wolfSSH Adds Support for Zephyr RTOS

The wolfSSH 1.4.15 release includes brand new support for the Zephyr RTOS. wolfSSH is a lightweight SSH library designed for embedded systems. It is a performant and low footprint solution, making it an ideal choice for IoT devices. The Zephyr RTOS is an open-source, scalable, and flexible real-time operating system tailored for resource-constrained devices. Its modular architecture and broad hardware support make it a popular choice for various embedded applications.

wolfSSH is introduced as a new module in the Zephyr ecosystem. Necessary steps to get started include setting up wolfSSH as a Zephyr module, modifying the west manifest, and finally building your project. In-depth instructions to set up wolfSSH with Zephyr can be found at the wolfSSH Github.

If you have questions about any of the above, please contact us at facts@wolfSSL.com or call us at +1 425 245 8247.

Download wolfSSL Now

Skipping the Cookie Exchange in DTLS 1.3

wolfSSL 5.6.6 introduces the option for DTLS 1.3 servers to skip the cookie exchange on a session resumption. The cookie exchange is a security mechanism employed during the resumption of a DTLS 1.3 session. When a client wants to resume a previous DTLS 1.3 session, it sends a session ticket to the server, which may respond by issuing a “cookie” to the client. This cookie serves as a challenge-response mechanism, requiring the client to present it during the resumption attempt. The purpose of this exchange is for the client to demonstrate reachability at their apparent network address. In some cases, you may choose to skip the cookie exchange if the client presents a valid ticket or pre-shared key (PSK).

To resume a DTLS 1.3 session without the cookie exchange:

  • Compile wolfSSL with WOLFSSL_DTLS13_NO_HRR_ON_RESUME defined. Either:
    • When compiling with configure add CPPFLAGS=-DWOLFSSL_DTLS13_NO_HRR_ON_RESUME
    • When compiling with user settings add #define WOLFSSL_DTLS13_NO_HRR_ON_RESUME
  • Call wolfSSL_dtls13_no_hrr_on_resume(ssl, 1) on the WOLFSSL object to disable the cookie exchange on resumption
  • Continue like with a normal connection

If you have any questions about using DTLS 1.3 in wolfSSL, please contact us at facts@wolfSSL.com or call us at +1 425 245 8247.

Download wolfSSL Now

Live Webinar: Solutions for the Satellite Industry

Get ready to learn the best practice for satellite cybersecurity with wolfSSL.

Join us for a webinar on “Solutions for the Satellite Industry” on February 8th at 10 am PT presented by wolfSSL Software Engineer, András. He will delve into robust solutions and best practices to safeguard satellite cybersecurity. This webinar is a must-attend for professionals in the aerospace and cybersecurity industries.

Watch the webinar here: Solutions for the Satellite Industry

Sneak Peek of the webinar:

  • Introduction to wolfSSL
  • Key wolfSSL Technologies for Satellite Security
  • High-Quality SSL/TLS Testing
  • Q&A

Don’t miss out on this opportunity to gain insights into the latest advancements in satellite cybersecurity. András will guide you through how FIPS, wolfBoot (Secure Boot), wolfTPM, wolfEntropy, and SSL/ TLS testing contribute to a secure satellite environment. Discover how wolfSSL conducts testing to ensure the highest level of security in SSL/TLS protocols. Watch now and get answers to your specific questions from András.

As always, our webinars will include Q&A sessions throughout. If you have questions about any of the above, please contact us at facts@wolfSSL.com or call us at +1 425 245 8247.

Download wolfSSL Now

Overview of Testing in wolfSSL

The security of wolfSSL products is always on the wolfSSL team’s mind and holds high importance. Conducting regular, diligent, and well-planned testing helps maintain wolfSSL’s robustness and security. The wolfSSL team strives to write and maintain clean, readable, and understandable code.

  1. API Unit Testing: Unit tests are in place to test API functions for correct behavior. This helps maintain library consistency across releases and as the code evolves. It ensures delivery of a high quality, well tested API to end users with each software release. API unit tests are run with each “make check” of wolfSSL.
  2. Cipher Suite Testing: wolfSSL supports an extensive list of cipher suites, which are all tested with every “make check” using the wolfSSL example client and example server. Each cipher suite is tested not only in the default configuration, but also in non-blocking mode and with client authentication both turned on and off.
  3. Algorithm Testing: The security of the SSL/TLS implementation depends on the correctness and robustness of the underlying cryptography library, wolfCrypt. The wolfssl team tests all algorithms using NIST test vectors in addition to running a CAVP test harness used for FIPS 140-2 and 140-3 validations. Testing is done on both big and little endian platforms for portability.
  4. Benchmark Testing: The wolfSSL team engages in the ever expanding universe of benchmark testing, taking into consideration sizing, transmission rates, connection speeds, and cryptography performance. A version of the benchmark suite is included in every download for users to enjoy!
  5. Static Analysis: wolfSSL does static analysis on the entire codebase using not only one, but multiple different static analysis tools. Currently Coverity Scan, CodeSonar, clang scan-build, and Facebook infer. These tools help to automatically find bugs including those on low-traffic code paths.
  6. Detecting Memory Errors: Memory errors are mitigated by using valgrind on a regular and automated basis. This helps find memory errors including invalid access, use of undefined values, incorrect freeing of dynamic memory, and memory leaks.
  7. Interop Testing: Interoperability checks are done with other Open Source TLS implementations, including OpenSSL, BoringSSL, and GnuTLS. This helps to catch any protocol implementation errors in either wolfSSL or the implementation being tested against. Testing is also done outside of a closed environment by connecting to servers in the real world running unknown SSL/TLS implementations.
  8. Real World Builds: Builds with a series of ‘real’ applications, like cURL, wget, pppd, OpenSSH, stunnel, lighttpd, etc. For some wolfSSL customers with top level support, the wolfSSL team also tests building the latest library version against those customer applications.
  9. Compiler Testing: Some users compile wolfSSL with a variety of different compilers. As such, wolfSSL tests compilation with many different compilers and toolchains including but not limited to: gcc/g++, clang, icc, Visual Studio, CodeWarrior, KDS, LPCXpresso, MPLAB XC, TI CCS, Keil, IAR, Espressif IDF, Cygwin, MinGW, CrossWorks, Arduino, Wind River Workbench.
  10. Peer Review: More eyes on a codebase reduces bugs that end up in a final product. Internally, the wolfSSL team operates using a “Fork and Pull Request” model. This means that every commit that makes it into the wolfSSL master branch has been reviewed and tested by a minimum of two engineers.
  11. Code size increase monitoring: wolfSSL has tests that give alarms when a particular commit greatly increases the code size for a particular build. Active Monitoring of how much the code has grown since the last release ensures that it is within an acceptable range.
  12. Third Party Testing: wolfSSL code is regularly reviewed by university researchers, customer and user security teams, FIPS and certification labs, and other Open Source users. This helps put more eyes on the code and product architecture.
  13. Fuzz Testing: wolfSSL tests using several different software fuzzers, including an in-memory fuzzer, a network fuzzer, OSS-fuzz, libfuzzer, tlsfuzzer, and AFL. Fuzz testing bombards the program with invalid, unexpected, and random data that then allows for observing if there are potential memory leaks or logic errors. This allows us to catch bugs that could turn into potential vulnerabilities if released in a final release.
  14. Protocol Analysis: TLS-Attacker, a Java-based framework for analyzing TLS libraries, helps us analyze that wolfSSL correctly conforms to the SSL/TLS specification.
  15. Continuous Integration (CI): Leveraging Jenkins as well as GitHub Actions, allows wolfSSL to run tests on each commit submitted to the wolfSSL code repository. Tests run on each commit include testing of the FIPS build, numerous build options (customer/user/common), running valgrind, and doing static analysis with scan-build.
  16. Nightly Test Cycle: Each night extended tests are run that last longer than the typical ones during the work day. These extended tests are more in-depth than CI testing and puts results in wolfSSL engineers’ inboxes each morning. Some tests included in the nightly cycle include extended build option testing on multiple platforms with multiple compilers, and extended fuzz testing.

If you have specific questions about how the wolfSSL team tests, please contact us at facts@wolfssl.com or call us at +1 425 245 8247. If you would like the wolfSSL team to include your SSL/TLS or crypto implementation in interop testing, please let us know! Likewise, if you would like to include wolfSSL in your own test framework, the wolfSSL team would be happy to discuss.

Download wolfSSL Now

wolfSSL Adds Support for 0.5-RTT Data in (D)TLS 1.3

(D)TLS 1.3 support for 0.5-RTT (round trip time) data has been introduced to wolfSSL in the latest release (5.6.6). 0.5-RTT data is an optimization in (D)TLS 1.3 that significantly reduces latency and improves overall performance of application data. The full handshake requires two full round trips to start sending data while this functionality allows the server to send application data along with its final flight of handshake messages. This new addition works well with our support for early data (also known as 0-RTT data). An embedded device is able to resume a connection, send early data with its connection request, and receive a response immediately within one RTT.


    	Client                                           	Server

    	ClientHello         	-------->
                                                    	ServerHello
                                          	EncryptedExtensions
                                          	CertificateRequest
                                                 	Certificate
                                           	CertificateVerify
                                                     	Finished
                            	<--------   	0.5-RTT Application Data
    	Certificate
    	CertificateVerify
    	Finished           	-------->
    	Application Data  	<------->    	Application Data

Diagram showing 0.5-RTT data in a full TLS 1.3 handshake

If you would like to learn more about (D)TLS 1.3 in wolfSSL, please contact us at facts@wolfSSL.com or call us at +1 425 245 8247.

Download wolfSSL Now

Posts navigation

1 2