| .. _bluetooth-arch: |
| |
| Stack Architecture |
| ################## |
| |
| Overview |
| ******** |
| |
| This page describes the software architecture of Zephyr's Bluetooth protocol |
| stack. |
| |
| .. note:: |
| Zephyr supports mainly Bluetooth Low Energy (BLE), the low-power |
| version of the Bluetooth specification. Zephyr also has limited support |
| for portions of the BR/EDR Host. Throughout this architecture document we |
| use BLE interchangeably for Bluetooth except when noted. |
| |
| .. _bluetooth-layers: |
| |
| BLE Layers |
| ========== |
| |
| There are 3 main layers that together constitute a full Bluetooth Low Energy |
| protocol stack: |
| |
| * **Host**: This layer sits right below the application, and is comprised of |
| multiple (non real-time) network and transport protocols enabling |
| applications to communicate with peer devices in a standard and interoperable |
| way. |
| * **Controller**: The Controller implements the Link Layer (LE LL), the |
| low-level, real-time protocol which provides, in conjunction with the Radio |
| Hardware, standard-interoperable over-the-air communication. The LL schedules |
| packet reception and transmission, guarantees the delivery of data, and |
| handles all the LL control procedures. |
| * **Radio Hardware**: Hardware implements the required analog and digital |
| baseband functional blocks that permit the Link Layer firmware to send and |
| receive in the 2.4GHz band of the spectrum. |
| |
| .. _bluetooth-hci: |
| |
| Host Controller Interface |
| ========================= |
| |
| The `Bluetooth Specification`_ describes the format in which a Host must |
| communicate with a Controller. This is called the Host Controller Interface |
| (HCI) protocol. HCI can be implemented over a range of different physical |
| transports like UART, SPI, or USB. This protocol defines the commands that a Host |
| can send to a Controller and the events that it can expect in return, and also |
| the format for user and protocol data that needs to go over the air. The HCI |
| ensures that different Host and Controller implementations can communicate |
| in a standard way making it possible to combine Hosts and Controllers from |
| different vendors. |
| |
| .. _bluetooth-configs: |
| |
| Configurations |
| ============== |
| |
| The three separate layers of the protocol and the standardized interface make |
| it possible to implement the Host and Controller on different platforms. The two |
| following configurations are commonly used: |
| |
| * **Single-chip configuration**: In this configuration, a single microcontroller |
| implements all three layers and the application itself. This can also be called a |
| system-on-chip (SoC) implementation. In this case the BLE Host and the BLE |
| Controller communicate directly through function calls and queues in RAM. The |
| Bluetooth specification does not specify how HCI is implemented in this |
| single-chip configuration and so how HCI commands, events, and data flows between |
| the two can be implementation-specific. This configuration is well suited for |
| those applications and designs that require a small footprint and the lowest |
| possible power consumption, since everything runs on a single IC. |
| * **Dual-chip configuration**: This configuration uses two separate ICs, |
| one running the Application and the Host, and a second one with the Controller |
| and the Radio Hardware. This is sometimes also called a connectivity-chip |
| configuration. This configuration allows for a wider variety of combinations of |
| Hosts when using the Zephyr OS as a Controller. Since HCI ensures |
| interoperability among Host and Controller implementations, including of course |
| Zephyr's very own BLE Host and Controller, users of the Zephyr Controller can |
| choose to use whatever Host running on any platform they prefer. For example, |
| the host can be the Linux BLE Host stack (BlueZ) running on any processor |
| capable of supporting Linux. The Host processor may of course also run Zephyr |
| and the Zephyr OS BLE Host. Conversely, combining an IC running the Zephyr |
| Host with an external Controller that does not run Zephyr is also supported. |
| |
| .. _bluetooth-build-types: |
| |
| Build Types |
| =========== |
| |
| The Zephyr software stack as an RTOS is highly configurable, and in particular, |
| the BLE subsystem can be configured in multiple ways during the build process to |
| include only the features and layers that are required to reduce RAM and ROM |
| footprint as well as power consumption. Here's a short list of the different |
| BLE-enabled builds that can be produced from the Zephyr project codebase: |
| |
| * **Controller-only build**: When built as a BLE Controller, Zephyr includes |
| the Link Layer and a special application. This application is different |
| depending on the physical transport chosen for HCI: |
| |
| * :zephyr:code-sample:`bluetooth_hci_uart` |
| * :zephyr:code-sample:`bluetooth_hci_usb` |
| * :zephyr:code-sample:`bluetooth_hci_spi` |
| |
| This application acts as a bridge between the UART, SPI or USB peripherals and |
| the Controller subsystem, listening for HCI commands, sending application data |
| and responding with events and received data. A build of this type sets the |
| following Kconfig option values: |
| |
| * :kconfig:option:`CONFIG_BT` ``=y`` |
| * :kconfig:option:`CONFIG_BT_HCI` ``=y`` |
| * :kconfig:option:`CONFIG_BT_HCI_RAW` ``=y`` |
| * :kconfig:option:`CONFIG_BT_CTLR` ``=y`` |
| * :kconfig:option:`CONFIG_BT_LL_SW_SPLIT` ``=y`` (if using the open source Link Layer) |
| |
| * **Host-only build**: A Zephyr OS Host build will contain the Application and |
| the BLE Host, along with an HCI driver (UART or SPI) to interface with an |
| external Controller chip. |
| A build of this type sets the following Kconfig option values: |
| |
| * :kconfig:option:`CONFIG_BT` ``=y`` |
| * :kconfig:option:`CONFIG_BT_HCI` ``=y`` |
| * :kconfig:option:`CONFIG_BT_CTLR` ``=n`` |
| |
| All of the samples located in ``samples/bluetooth`` except for the ones |
| used for Controller-only builds can be built as Host-only |
| |
| * **Combined build**: This includes the Application, the Host and the |
| Controller, and it is used exclusively for single-chip (SoC) configurations. |
| A build of this type sets the following Kconfig option values: |
| |
| * :kconfig:option:`CONFIG_BT` ``=y`` |
| * :kconfig:option:`CONFIG_BT_HCI` ``=y`` |
| * :kconfig:option:`CONFIG_BT_CTLR` ``=y`` |
| * :kconfig:option:`CONFIG_BT_LL_SW_SPLIT` ``=y`` (if using the open source Link Layer) |
| |
| All of the samples located in ``samples/bluetooth`` except for the ones |
| used for Controller-only builds can be built as Combined |
| |
| The picture below shows the SoC or single-chip configuration when using a Zephyr |
| combined build (a build that includes both a BLE Host and a Controller in the |
| same firmware image that is programmed onto the chip): |
| |
| .. figure:: img/ble_cfg_single.png |
| :align: center |
| :alt: BLE Combined build on a single chip |
| |
| A Combined build on a Single-Chip configuration |
| |
| When using connectivity or dual-chip configurations, several Host and Controller |
| combinations are possible, some of which are depicted below: |
| |
| .. figure:: img/ble_cfg_dual.png |
| :align: center |
| :alt: BLE dual-chip configuration builds |
| |
| Host-only and Controller-only builds on dual-chip configurations |
| |
| When using a Zephyr Host (left side of image), two instances of Zephyr OS |
| must be built with different configurations, yielding two separate images that |
| must be programmed into each of the chips respectively. The Host build image |
| contains the application, the BLE Host and the selected HCI driver (UART or |
| SPI), while the Controller build runs either the |
| :zephyr:code-sample:`bluetooth_hci_uart`, or the |
| :zephyr:code-sample:`bluetooth_hci_spi` app to provide an interface to |
| the BLE Controller. |
| |
| This configuration is not limited to using a Zephyr OS Host, as the right side |
| of the image shows. One can indeed take one of the many existing GNU/Linux |
| distributions, most of which include Linux's own BLE Host (BlueZ), to connect it |
| via UART or USB to one or more instances of the Zephyr OS Controller build. |
| BlueZ as a Host supports multiple Controllers simultaneously for applications |
| that require more than one BLE radio operating at the same time but sharing the |
| same Host stack. |
| |
| Source tree layout |
| ****************** |
| |
| The stack is split up as follows in the source tree: |
| |
| ``subsys/bluetooth/host`` |
| :ref:`The host stack <bluetooth_le_host>`. This is where the HCI command and |
| event handling as well as connection tracking happens. The implementation of |
| the core protocols such as L2CAP, ATT, and SMP is also here. |
| |
| ``subsys/bluetooth/controller`` |
| :ref:`Bluetooth LE Controller <bluetooth-ctlr-arch>` implementation. |
| Implements the controller-side of HCI, the Link Layer as well as access to the |
| radio transceiver. |
| |
| ``include/bluetooth/`` |
| :ref:`Public API <bluetooth_api>` header files. These are the header files |
| applications need to include in order to use Bluetooth functionality. |
| |
| ``drivers/bluetooth/`` |
| HCI transport drivers. Every HCI transport needs its own driver. For example, |
| the two common types of UART transport protocols (3-Wire and 5-Wire) |
| have their own drivers. |
| |
| ``samples/bluetooth/`` |
| :zephyr:code-sample-category:`Sample Bluetooth code <bluetooth>`. This is a good reference to |
| get started with Bluetooth application development. |
| |
| ``tests/bluetooth/`` |
| Test applications. These applications are used to verify the |
| functionality of the Bluetooth stack, but are not necessary the best |
| source for sample code (see ``samples/bluetooth`` instead). |
| |
| ``doc/connectivity/bluetooth/`` |
| Extra documentation, such as PICS documents. |
| |
| .. _Bluetooth Specification: https://www.bluetooth.com/specifications/bluetooth-core-specification |