Join the esteemed senior security researcher and endpoint security engineer, as she takes you along a deep dive into the internals of the Windows 11 Operating System.
Covering Windows 11 “21H2”, the upcoming “22H1”, and Server 2022, you’ll unravel the secrets of how GRU bootkits, PLA software supply chain implants, NSA backdoors, and other kernel and firmware malware work. You’ll learn how they, and others, abuse various system functionality, obscure mechanisms, and data structures, in order to do their dirty work, and how you can
too defend against it!
You’ll observe and experiment with how kernel-mode code operates and how it can be subject to compromise by user-mode attackers wishing to elevate their privileges, as well as how to detect, both live and forensically, such attempts. Finally, you’ll learn about how CPU architecture deeply ties into OS design, and how Intel’s and AMD’s mistakes can lead to more pwnage. This course is only taught twice a year, and this is your one and only chance to attend it in Europe!
We’ll cover the new Windows 11 kernel changes, including Kernel Data Protection (KDP), eXtended Control Flow Guard (XFG), and Kernel Control-flow Enforcement Technology (KCET), and explain how the Trusted Platform Module (TPM) is used for Measured Boot. We’ll go inside the Octagon and learn about System Guard Runtime Assertions and the rewritten Secure Launch framework that leverages Intel TXT and AMD SKINIT for new DRTM-based attestation.
Of course, we’ll also discuss key Windows 10 fundamentals such as Virtual Trust Levels (VTL) combined with Virtualization Based Security (VBS), and how these technologies allow Hyper Visor Code Integrity (HVCI) and Kernel Control Flow Guard (KCFG) to prevent unsigned kernel code execution, even when faced with Ring 0 vulnerabilities, while also powering Biometric Isolation and Credential Guard, make pass-the-hash attacks virtually impossible. Enclaves and Attestation, both through Software Guard Extensions (SGX) and VBS, and TPM-based Measured Boot, will also be on the menu.
Windows 10 builds upon many Windows 8.1 mechanisms such as Protected Process Light and custom Code Signing Policies, so we’ll review this as well, plus new Windows 8 kernel features (AppContainer, Secure Boot, and more) relevant to driver operation and exploitation techniques will be discussed, including an overview of over two dozen new security mitigations that have been added to the operating system.
We’ll see how these changes to the architecture have dramatically constrained exploit techniques. Windows 7 kernel changes will be discussed too, such as the new Object Manager data structures.
Throughout the class, we’ll focus on using various techniques and tools to inspect the Windows kernel for consistency, tracing its operation, and editing it, as well as ways in which offensive and defensive attackers can mess with the system’s state in unexpected, “clean” ways. We’ll also give several examples of malicious and/or buggy drivers in a typical Windows system, as well as architectural bugs over Windows’ lifetime.
Attendees will receive a physical handout of the entire course materials for future reference, plus a full set of 40+ WinDbg scripts that the instructors have written over their lifetime, and all commands/outputs that were used in the course. Live paste-board sharing will be available to facilitate learning.
You’ll be exposed to low-level CPU details such as segmentation and task gates, things you probably thought didn’t matter since 1986 anymore, but which still drive core Windows architecture today. Never again will you think [gs:60h] is a magic constant. Both x86 and x64 will be covered and we might take a look at QC’s ARM64 SoC on Windows 10 depending on market success. Security features such as SMEP, SMAP, SGX, CET, UMIP will be part of the course, and we’ll see the facilities that Windows provides to use them. Finally, we’ll see how the hypervisor adds its own layer of security mechanisms using VTLs, SLAT, IOMMU and MBEC.
We’ll then move our focus toward understanding the behavior and operation of the Windows Kernel. Core topics such as interrupts, IRQLs, DPCs, APCs, system calls, user-mode callbacks, timers, scheduling and memory management will be discussed at the architectural level. You are expected to already be familiar with some of these ideas – for example, on the topic of memory management, it is not about how to use malloc, but rather about the complexities of and effects of the algorithms used by Windows when managing pages.
You will learn the various data structures used by bookkeeping and internal consistency and management of key system components such as the ALPC subsystem that powers RPC, as well as core mechanisms and objects such as threads, processes, and jobs, and how these fields can affect the operation of the system in ways that malicious code can control. You’ll see the various boundaries and containers that control code execution – from AppContainer to Application Package, to Fiber to Job to Silo, and discuss Critical, Secure, Pico and Minimal Processes.
You’ll learn about the Windows Memory Manager and its many bookkeeping data structures both at the virtual memory and physical memory layer and how they can both be used to identify hidden code at runtime, as well as used forensically for gathering data about an attack. We’ll also cover shared memory objects, and the dangers that lie within – including a few live samples of bugs nobody cares to fix. Interesting but not well-understood kernel components, such as Extension Hosts, Windows Notification Facility (WNF) and Callback Objects will be described, and opportunities for their misuse.
Finally, it’s not just all about the kernel! You’ll also discover how Windows’ Subsystem Model affects the execution of code and abstraction of various system components and we’ll take a look at the Windows Subsystem specifically and how extends its claws into the kernel through the window manager (Win32k.sys) and its data structures and behaviors will also be in the purview of our class. We will be peering into aspects of Win32k.sys that few have looked at before – except those that find new kernel vulnerabilities in it by the minute, and explain its separation into the Win32kbase and Win32kmin and Win32kfull components and continued evolution through concepts such as Core Messaging, and the removal of Simple Calls.
IMPORTANT: It’s helpful to understand x86/x64 assembly to take this course, but knowledge of obfuscation, packing, etc., is not required.
Basic knowledge of Windows, processor architecture, and operating systems is helpful – you should have some vague idea of what an interrupt is, and what is the difference between user and kernel mode (ring levels), a bit about virtual memory/paging, etc.
You must have a Windows machine to attend, and you should have the Windows Driver Kit 11 release for 21H2 or later (22000 / 2009), which you can freely grab from MSDN.
A virtual machine (VirtualBox or Hyper-V are strongly preferred – configured in UEFI + Hyper-V mode for best performance) is recommended with an installed version of Windows 11. Locally, any version of Windows 7 or above, 32-bit or 64-bit is fine – but it’s strongly preferred you bring a Windows 10 or 11 box. You should install the Windows Driver Kit on your host – not the VM. If you have a Linux or Mac device, then you may either install the Windows Driver Kit on the VM itself, or, better yet, use two separate virtual machines.
The instructors will use a 64-bit Windows 11 device, with 32-bit VMs.
GHIDRA/IDA/HexRays helpful, but not required.
Yarden Shafir started dancing at the age of 7, and later joined a rhythmic gymnastics team and competed during her teenage years. After her military service, she practiced pole dancing and fell in love with acrobatics. Today she performs aerial arts for the circus, trains whenever possible, and teaches lyra and silks in Israel, while also having a rich background of Windows Internals research originally at Sentinel One, followed by her current role as a Senior Software Engineer at CrowdStrike working on various EDR capabilities and EPP features.