172 lines
6.4 KiB
ReStructuredText
172 lines
6.4 KiB
ReStructuredText
.. _bus_emul:
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External Bus and Bus Connected Peripherals Emulators
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####################################################
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Overview
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========
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Zephyr supports a simple emulator framework to support testing of external peripheral drivers
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without requiring real hardware.
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Emulators are used to emulate external hardware devices, to support testing of
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various subsystems. For example, it is possible to write an emulator
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for an I2C compass such that it appears on the I2C bus and can be used
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just like a real hardware device.
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Emulators often implement special features for testing. For example a
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compass may support returning bogus data if the I2C bus speed is too
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high, or may return invalid measurements if calibration has not yet
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been completed. This allows for testing that high-level code can
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handle these situations correctly. Test coverage can therefore
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approach 100% if all failure conditions are emulated.
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Concept
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=======
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The diagram below shows application code / high-level tests at the top.
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This is the ultimate application we want to run.
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.. figure:: img/arch.svg
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:align: center
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:alt: Emulator architecture showing tests, emulators and drivers
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Below that are peripheral drivers, such as the AT24 EEPROM driver. We can test
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peripheral drivers using an emulation driver connected via a emulated I2C
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controller/emulator which passes I2C traffic from the AT24 driver to the AT24
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simulator.
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Separately we can test the STM32 and NXP I2C drivers on real hardware using API
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tests. These require some sort of device attached to the bus, but with this, we
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can validate much of the driver functionality.
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Putting the two together, we can test the application and peripheral code
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entirely on native_sim. Since we know that the I2C driver on the real hardware
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works, we should expect the application and peripheral drivers to work on the
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real hardware also.
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Using the above framework we can test an entire application (e.g. Embedded
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Controller) on native_sim using emulators for all non-chip drivers.
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With this approach we can:
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* Write individual tests for each driver (green), covering all failure modes,
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error conditions, etc.
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* Ensure 100% test coverage for drivers (green)
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* Write tests for combinations of drivers, such as GPIOs provided by an I2C GPIO
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expander driver talking over an I2C bus, with the GPIOs controlling a charger.
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All of this can work in the emulated environment or on real hardware.
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* Write a complex application that ties together all of these pieces and runs on
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native_sim. We can develop on a host, use source-level debugging, etc.
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* Transfer the application to any board which provides the required features
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(e.g. I2C, enough GPIOs), by adding Kconfig and devicetree fragments.
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Creating a Device Driver Emulator
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=================================
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The emulator subsystem is modeled on the :ref:`device_model_api`. You create
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an emulator instance using one of the :c:func:`EMUL_DT_DEFINE()` or
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:c:func:`EMUL_DT_INST_DEFINE()` APIs.
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Emulators for peripheral devices reuse the same devicetree node as the real
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device driver. This means that your emulator defines `DT_DRV_COMPAT` using the
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same ``compat`` value from the real driver.
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.. code-block:: C
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/* From drivers/sensor/bm160/bm160.c */
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#define DT_DRV_COMPAT bosch_bmi160
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/* From drivers/sensor/bmi160/emul_bmi160.c */
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#define DT_DRV_COMPAT bosch_bmi160
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The ``EMUL_DT_DEFINE()`` function accepts two API types:
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#. ``bus_api`` - This points to the API for the upstream bus that the emulator
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connects to. The ``bus_api`` parameter is required. The supported
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emulated bus types include I2C, SPI, eSPI, and MSPI.
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#. ``_backend_api`` - This points to the device-class specific backend API for
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the emulator. The ``_backend_api`` parameter is optional.
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The diagram below demonstrates the logical organization of the ``bus_api`` and
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``_backend_api`` using the BC1.2 charging detector driver as the model
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device-class.
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.. figure:: img/device_class_emulator.svg
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:align: center
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:alt: Device class example, demonstrating BC1.2 charging detectors.
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The real code is shown in green, while the emulator code is shown in yellow.
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The ``bus_api`` connects the BC1.2 emulators to the ``native_sim`` I2C
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controller. The real BC1.2 drivers are unchanged and operate exactly as if there
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was a physical I2C controller present in the system. The ``native_sim`` I2C
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controller uses the ``bus_api`` to initiate register reads and writes to the
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emulator.
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The ``_backend_api`` provides a mechanism for tests to manipulate the emulator
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out of band. Each device class defines it's own API functions. The backend API
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functions focus on high-level behavior and do not provide hooks for specific
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emulators.
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In the case of the BC1.2 charging detector the backend API provides functions
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to simulate connecting and disconnecting a charger to the emulated BC1.2 device.
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Each emulator is responsible for updating the correct vendor specific registers
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and potentially signalling an interrupt.
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Example test flow:
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#. Test registers BC1.2 detection callback using the Zephyr BC1.2 driver API.
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#. Test connects a charger using the BC1.2 emulator backend.
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#. Test verifies B1.2 detection callback invoked with correct charger type.
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#. Test disconnects a charger using the BC1.2 emulator backend.
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With this architecture, the same test can be used will all supported drivers in
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the same driver class.
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Available Emulators
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===================
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Zephyr includes the following emulators:
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* I2C emulator driver, allowing drivers to be connected to an emulator so that
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tests can be performed without access to the real hardware
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* SPI emulator driver, which does the same for SPI
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* eSPI emulator driver, which does the same for eSPI. The emulator is being
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developed to support more functionalities.
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* MSPI emulator driver, allowing drivers to be connected to an emulator so that
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tests can be performed without access to the real hardware.
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Samples
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=======
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Here are some examples present in Zephyr:
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#. Bosch BMI160 sensor driver connected via both I2C and SPI to an emulator:
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.. zephyr-app-commands::
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:app: tests/drivers/sensor/accel/
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:board: native_sim
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:goals: build
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#. The same test can be built with a second EEPROM which is an Atmel AT24 EEPROM driver
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connected via I2C an emulator:
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.. zephyr-app-commands::
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:app: tests/drivers/eeprom/api
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:board: native_sim
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:goals: build
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:gen-args: -DDTC_OVERLAY_FILE=at2x_emul.overlay -DOVERLAY_CONFIG=at2x_emul.conf
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API Reference
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*************
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.. doxygengroup:: io_emulators
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