Operating-system framework

The Genode OS framework is the implementation of the Genode architecture. It is a tool kit for building highly secure special-purpose operating systems. It scales from embedded systems with as little as 4 MB of memory to highly dynamic general-purpose workloads.

The system is based on a recursive structure. Each program is executed in a dedicated sandbox and gets granted only those access rights and resources that are required to fulfill its specific purpose. Programs can create and manage sub-sandboxes out of their own resources, thereby forming hierarchies where policies can be applied at each level. The framework provides mechanisms to let programs communicate with each other and trade their resources, but only in strictly-defined manners. Thanks to this rigid regime, the attack surface of security-critical functions can be reduced by orders of magnitude compared to contemporary operating systems.

The framework aligns the construction principles of microkernels with Unix philosophy. In line with Unix philosophy, Genode is a collection of small building blocks, out of which sophisticated systems can be composed. But unlike Unix, those building blocks include not only applications but also all classical OS functionalities including kernels, device drivers, file systems, and protocol stacks.

CPU architectures

Genode supports the x86 (32 and 64 bit), ARM (32 bit), and RISC-V (64 bit) CPU architectures. On x86, modern architectural features such as IOMMUs and hardware virtualization can be utilized. On ARM, Genode is able to take advantage of TrustZone and virtualization technology.


Genode can be deployed on a variety of different kernels including most members of the L4 family (NOVA, seL4, Fiasco.OC, OKL4 v2.1, L4ka::Pistachio, L4/Fiasco). Furthermore, it can be used on top of the Linux kernel to attain rapid development-test cycles during development. Additionally, the framework is accompanied with a custom microkernel that has been specifically developed for Genode and thereby further reduces the complexity of the trusted computing base compared to other kernels.


Genode supports virtualization at different levels:

  • On NOVA, faithful virtualization via VirtualBox allows the execution of unmodified guest operating systems as Genode subsystems. Alternatively, the Seoul virtual machine monitor can be used to run unmodified Linux-based guest OSes.

  • With Noux, there exists a runtime environment for Unix software such as GNU coreutils, bash, GCC, binutils, and findutils.

  • On ARM, Genode can be used as TrustZone monitor, or as a virtual machine monitor that facilitates ARM's virtualization extensions.

Building blocks

There exist hundreds of ready-to-use components such as

  • Device drivers for most common PC peripherals including networking, storage, display, USB, PS/2, Intel wireless, and audio output.

  • Device drivers for a variety of ARM-based SoCs such as Texas Instruments OMAP4, Samsung Exynos5, and FreeScale i.MX.

  • A GUI stack including a low-complexity GUI server, window management, and widget toolkits such as Qt5.

  • Networking components such as TCP/IP stacks and packet-level network services.