.. _rpi_pico: Raspberry Pi Pico ################# Overview ******** The Raspberry Pi Pico is a small, low-cost, versatile board from Raspberry Pi. It is equipped with an RP2040 SoC, an on-board LED, a USB connector, and an SWD interface. The USB bootloader allows it to be flashed without any adapter, in a drag-and-drop manner. It is also possible to flash and debug the Pico with its SWD interface, using an external adapter. Hardware ******** - Dual core Arm Cortex-M0+ processor running up to 133MHz - 264KB on-chip SRAM - 2MB on-board QSPI flash with XIP capabilities - 26 GPIO pins - 3 Analog inputs - 2 UART peripherals - 2 SPI controllers - 2 I2C controllers - 16 PWM channels - USB 1.1 controller (host/device) - 8 Programmable I/O (PIO) for custom peripherals - On-board LED - 1 Watchdog timer peripheral .. figure:: ../../../../../../../../../zephyr/boards/arm/rpi_pico/doc/img/rpi_pico.jpg :align: center :alt: Raspberry Pi Pico Raspberry Pi Pico (Image courtesy of Raspberry Pi) Supported Features ================== The rpi_pico board configuration supports the following hardware features: .. list-table:: :header-rows: 1 * - Peripheral - Kconfig option - Devicetree compatible * - NVIC - N/A - :dtcompatible:`arm,v6m-nvic` * - UART - :kconfig:option:`CONFIG_SERIAL` - :dtcompatible:`raspberrypi,pico-uart` * - GPIO - :kconfig:option:`CONFIG_GPIO` - :dtcompatible:`raspberrypi,pico-gpio` * - ADC - :kconfig:option:`CONFIG_ADC` - :dtcompatible:`raspberrypi,pico-adc` * - I2C - :kconfig:option:`CONFIG_I2C` - :dtcompatible:`snps,designware-i2c` * - SPI - :kconfig:option:`CONFIG_SPI` - :dtcompatible:`raspberrypi,pico-spi` * - USB Device - :kconfig:option:`CONFIG_USB_DEVICE_STACK` - :dtcompatible:`raspberrypi,pico-usbd` * - HWINFO - :kconfig:option:`CONFIG_HWINFO` - N/A * - Watchdog Timer (WDT) - :kconfig:option:`CONFIG_WATCHDOG` - :dtcompatible:`raspberrypi,pico-watchdog` * - PWM - :kconfig:option:`CONFIG_PWM` - :dtcompatible:`raspberrypi,pico-pwm` * - Flash - :kconfig:option:`CONFIG_FLASH` - :dtcompatible:`raspberrypi,pico-flash` Pin Mapping =========== The peripherals of the RP2040 SoC can be routed to various pins on the board. The configuration of these routes can be modified through DTS. Please refer to the datasheet to see the possible routings for each peripheral. Default Zephyr Peripheral Mapping: ---------------------------------- .. rst-class:: rst-columns - UART0_TX : P0 - UART0_RX : P1 - I2C0_SDA : P4 - I2C0_SCL : P5 - I2C1_SDA : P14 - I2C1_SCL : P15 - SPI0_RX : P16 - SPI0_CSN : P17 - SPI0_SCK : P18 - SPI0_TX : P19 - ADC_CH0 : P26 - ADC_CH1 : P27 - ADC_CH2 : P28 - ADC_CH3 : P29 Programming and Debugging ************************* Flashing ======== Using SEGGER JLink ------------------ You can Flash the rpi_pico with a SEGGER JLink debug probe as described in :ref:`Building, Flashing and Debugging `. Here is an example of building and flashing the :ref:`blinky-sample` application. .. zephyr-app-commands:: :zephyr-app: samples/basic/blinky :board: rpi_pico :goals: build .. code-block:: bash west flash --runner jlink Using OpenOCD ------------- To use PicoProbe, You must configure **udev**. Create a file in /etc/udev.rules.d with any name, and write the line below. .. code-block:: bash ATTRS{idVendor}=="2e8a", ATTRS{idProduct}=="0004", MODE="660", GROUP="plugdev", TAG+="uaccess" This example is valid for the case that the user joins to `plugdev` groups. The Raspberry Pi Pico has an SWD interface that can be used to program and debug the on board RP2040. This interface can be utilized by OpenOCD. However, to use it with the RP2040, a `fork of OpenOCD supporting RP2040`_ is needed. If you are using a Debian based system (including RaspberryPi OS, Ubuntu. and more), using the `pico_setup.sh`_ script is a convenient way to set up the forked version of OpenOCD. Depending on the interface used (such as JLink), you might need to checkout to a branch that supports this interface, before proceeding. Build and install OpenOCD as described in the README. Here is an example of building and flashing the :ref:`blinky-sample` application. .. zephyr-app-commands:: :zephyr-app: samples/basic/blinky :board: rpi_pico :goals: build flash :gen-args: -DOPENOCD=/usr/local/bin/openocd -DOPENOCD_DEFAULT_PATH=/usr/local/share/openocd/scripts -DRPI_PICO_DEBUG_ADAPTER=picoprobe Set the environment variables **OPENOCD** to `/usr/local/bin/openocd` and **OPENOCD_DEFAULT_PATH** to `/usr/local/share/openocd/scripts`. This should work with the OpenOCD that was installed with the default configuration. This configuration also works with an environment that is set up by the `pico_setup.sh`_ script. **RPI_PICO_DEBUG_ADAPTER** specifies what debug adapter is used for debugging. If **RPI_PICO_DEBUG_ADAPTER** was not assigned, `picoprobe` is used by default. The other supported adapters are `raspberrypi-swd`, `jlink` and `blackmagicprobe`. How to connect `picoprobe` and `raspberrypi-swd` is described in `Getting Started with Raspberry Pi Pico`_. Any other SWD debug adapter maybe also work with this configuration. The value of **RPI_PICO_DEBUG_ADAPTER** is cached, so it can be omitted from `west flash` and `west debug` if it was previously set while running `west build`. **RPI_PICO_DEBUG_ADAPTER** is used in an argument to OpenOCD as `"source [find interface/${RPI_PICO_DEBUG_ADAPTER}.cfg]"`. Thus, **RPI_PICO_DEBUG_ADAPTER** needs to be assigned the file name of the debug adapter. You can also flash the board with the following command that directly calls OpenOCD (assuming a SEGGER JLink adapter is used): .. code-block:: console $ openocd -f interface/jlink.cfg -c 'transport select swd' -f target/rp2040.cfg -c "adapter speed 2000" -c 'targets rp2040.core0' -c 'program path/to/zephyr.elf verify reset exit' Using UF2 --------- If you don't have an SWD adapter, you can flash the Raspberry Pi Pico with a UF2 file. By default, building an app for this board will generate a `build/zephyr/zephyr.uf2` file. If the Pico is powered on with the `BOOTSEL` button pressed, it will appear on the host as a mass storage device. The UF2 file should be drag-and-dropped to the device, which will flash the Pico. Debugging ========= The SWD interface can also be used to debug the board. To achieve this, you can either use SEGGER JLink or OpenOCD. Using SEGGER JLink ------------------ Use a SEGGER JLink debug probe and follow the instruction in :ref:`Building, Flashing and Debugging`. Using OpenOCD ------------- Install OpenOCD as described for flashing the board. .. note:: `fork of OpenOCD supporting RP2040`_ does not provide ZephyrRTOS enhancement. (No RTOS awareness. Thus, can't recognize threads.) Here is an example for debugging the :ref:`blinky-sample` application. .. zephyr-app-commands:: :zephyr-app: samples/basic/blinky :board: rpi_pico :maybe-skip-config: :goals: debug :gen-args: -DOPENOCD=/usr/local/bin/openocd -DOPENOCD_DEFAULT_PATH=/usr/local/share/openocd/scripts -DRPI_PICO_DEBUG_ADAPTER=raspberrypi-swd As with flashing, you can specify the debug adapter by specifying **RPI_PICO_DEBUG_ADAPTER** at `west build` time. No needs to specify it at `west debug` time. You can also debug with OpenOCD and gdb launching from command-line. Run the following command: .. code-block:: console $ openocd -f interface/jlink.cfg -c 'transport select swd' -f target/rp2040.cfg -c "adapter speed 2000" -c 'targets rp2040.core0' On another terminal, run: .. code-block:: console $ gdb-multiarch Inside gdb, run: .. code-block:: console (gdb) tar ext :3333 (gdb) file path/to/zephyr.elf You can then start debugging the board. .. target-notes:: .. _fork of OpenOCD supporting RP2040: https://github.com/raspberrypi/openocd .. _pico_setup.sh: https://raw.githubusercontent.com/raspberrypi/pico-setup/master/pico_setup.sh .. _Getting Started with Raspberry Pi Pico: https://datasheets.raspberrypi.com/pico/getting-started-with-pico.pdf