.. _introducing_zephyr: Introduction ############ The Zephyr OS is based on a small-footprint kernel designed for use on resource-constrained and embedded systems: from simple embedded environmental sensors and LED wearables to sophisticated embedded controllers, smart watches, and IoT wireless applications. The Zephyr kernel supports multiple architectures, including: - ARCv2 (EM and HS) and ARCv3 (HS6X) - ARMv6-M, ARMv7-M, and ARMv8-M (Cortex-M) - ARMv7-A and ARMv8-A (Cortex-A, 32- and 64-bit) - ARMv7-R, ARMv8-R (Cortex-R, 32- and 64-bit) - Intel x86 (32- and 64-bit) - MIPS (MIPS32 Release 1 specification) - NIOS II Gen 2 - RISC-V (32- and 64-bit) - SPARC V8 - Tensilica Xtensa The full list of supported boards based on these architectures can be found :ref:`here `. Licensing ********* Zephyr is permissively licensed using the `Apache 2.0 license`_ (as found in the ``LICENSE`` file in the project's `GitHub repo`_). There are some imported or reused components of the Zephyr project that use other licensing, as described in :ref:`Zephyr_Licensing`. .. _Apache 2.0 license: https://github.com/zephyrproject-rtos/zephyr/blob/main/LICENSE .. _GitHub repo: https://github.com/zephyrproject-rtos/zephyr Distinguishing Features *********************** Zephyr offers a large and ever growing number of features including: **Extensive suite of Kernel services** Zephyr offers a number of familiar services for development: * *Multi-threading Services* for cooperative, priority-based, non-preemptive, and preemptive threads with optional round robin time-slicing. Includes POSIX pthreads compatible API support. * *Interrupt Services* for compile-time registration of interrupt handlers. * *Memory Allocation Services* for dynamic allocation and freeing of fixed-size or variable-size memory blocks. * *Inter-thread Synchronization Services* for binary semaphores, counting semaphores, and mutex semaphores. * *Inter-thread Data Passing Services* for basic message queues, enhanced message queues, and byte streams. * *Power Management Services* such as overarching, application or policy-defined, System Power Management and fine-grained, driver-defined, Device Power Management. **Multiple Scheduling Algorithms** Zephyr provides a comprehensive set of thread scheduling choices: * Cooperative and Preemptive Scheduling * Earliest Deadline First (EDF) * Meta IRQ scheduling implementing "interrupt bottom half" or "tasklet" behavior * Timeslicing: Enables time slicing between preemptible threads of equal priority * Multiple queuing strategies: * Simple linked-list ready queue * Red/black tree ready queue * Traditional multi-queue ready queue .. _zephyr_intro_configurability: **Highly configurable / Modular for flexibility** Allows an application to incorporate *only* the capabilities it needs as it needs them, and to specify their quantity and size. **Cross Architecture** Supports a wide variety of :ref:`supported boards` with different CPU architectures and developer tools. Contributions have added support for an increasing number of SoCs, platforms, and drivers. **Memory Protection** Implements configurable architecture-specific stack-overflow protection, kernel object and device driver permission tracking, and thread isolation with thread-level memory protection on x86, ARC, and ARM architectures, userspace, and memory domains. For platforms without MMU/MPU and memory constrained devices, supports combining application-specific code with a custom kernel to create a monolithic image that gets loaded and executed on a system's hardware. Both the application code and kernel code execute in a single shared address space. **Compile-time resource definition** Allows system resources to be defined at compile-time, which reduces code size and increases performance for resource-limited systems. **Optimized Device Driver Model** Provides a consistent device model for configuring the drivers that are part of the platform/system and a consistent model for initializing all the drivers configured into the system and allows the reuse of drivers across platforms that have common devices/IP blocks. **Devicetree Support** Use of :ref:`devicetree ` to describe hardware. Information from devicetree is used to create the application image. **Native Networking Stack supporting multiple protocols** Networking support is fully featured and optimized, including LwM2M and BSD sockets compatible support. OpenThread support (on Nordic chipsets) is also provided - a mesh network designed to securely and reliably connect hundreds of products around the home. **Bluetooth Low Energy 5.0 support** Bluetooth 5.0 compliant (ESR10) and Bluetooth Low Energy Controller support (LE Link Layer). Includes Bluetooth Mesh and a Bluetooth qualification-ready Bluetooth controller. * Generic Access Profile (GAP) with all possible LE roles * Generic Attribute Profile (GATT) * Pairing support, including the Secure Connections feature from Bluetooth 4.2 * Clean HCI driver abstraction * Raw HCI interface to run Zephyr as a Controller instead of a full Host stack * Verified with multiple popular controllers * Highly configurable Mesh Support: * Relay, Friend Node, Low-Power Node (LPN) and GATT Proxy features * Both Provisioning bearers supported (PB-ADV & PB-GATT) * Highly configurable, fitting in devices with at least 16k RAM **Native Linux, macOS, and Windows Development** A command-line CMake build environment runs on popular developer OS systems. A native port (:ref:`native_sim `) lets you build and run Zephyr as a native application on Linux, aiding development and testing. **Virtual File System Interface with ext2, FatFs, and LittleFS Support** ext2, LittleFS and FatFS support; FCB (Flash Circular Buffer) for memory constrained applications. **Powerful multi-backend logging Framework** Support for log filtering, object dumping, panic mode, multiple backends (memory, networking, filesystem, console, ...) and integration with the shell subsystem. **User friendly and full-featured Shell interface** A multi-instance shell subsystem with user-friendly features such as autocompletion, wildcards, coloring, metakeys (arrows, backspace, ctrl+u, etc.) and history. Support for static commands and dynamic sub-commands. **Settings on non-volatile storage** The settings subsystem gives modules a way to store persistent per-device configuration and runtime state. Settings items are stored as key-value pair strings. **Non-volatile storage (NVS)** NVS allows storage of binary blobs, strings, integers, longs, and any combination of these. **Native port** :ref:`Native sim ` allows running Zephyr as a Linux application with support for various subsystems and networking. .. include:: ../../README.rst :start-after: start_include_here Fundamental Terms and Concepts ****************************** See :ref:`glossary`