ESP32¶
Overview¶
ESP32 is a series of low cost, low power system on a chip microcontrollers with integrated Wi-Fi & dual-mode Bluetooth. The ESP32 series employs a Tensilica Xtensa LX6 microprocessor in both dual-core and single-core variations. ESP32 is created and developed by Espressif Systems, a Shanghai-based Chinese company, and is manufactured by TSMC using their 40nm process. 1
The features include the following:
Dual core Xtensa microprocessor (LX6), running at 160 or 240MHz
520KB of SRAM
802.11b/g/n/e/i
Bluetooth v4.2 BR/EDR and BLE
Various peripherals:
12-bit ADC with up to 18 channels
2x 8-bit DACs
10x touch sensors
Temperature sensor
4x SPI
2x I2S
2x I2C
3x UART
SD/SDIO/MMC host
Slave (SDIO/SPI)
Ethernet MAC
CAN bus 2.0
IR (RX/TX)
Motor PWM
LED PWM with up to 16 channels
Hall effect sensor
Cryptographic hardware acceleration (RNG, ECC, RSA, SHA-2, AES)
5uA deep sleep current
System requirements¶
Prerequisites¶
The ESP32 toolchain xtensa-esp32-elf
is required to build this port.
The toolchain installation can be performed in two ways:
Automatic installation
west espressif install
Note
By default, the toolchain will be downloaded and installed under $HOME/.espressif directory (%USERPROFILE%/.espressif on Windows).
Manual installation
Follow the ESP32 Toolchain link to download proper OS package version. Unpack the toolchain file to a known location as it will be required for environment path configuration.
Build Environment Setup¶
Some variables must be exported into the environment prior to building this port. Find more information at Setting Variables on how to keep this settings saved in you environment.
Note
In case of manual toolchain installation, set ESPRESSIF_TOOLCHAIN_PATH
accordingly.
Otherwise, set toolchain path as below. If necessary, update the version folder path as in esp-2020r3-8.4.0
.
On Linux and macOS:
export ZEPHYR_TOOLCHAIN_VARIANT="espressif"
export ESPRESSIF_TOOLCHAIN_PATH="${HOME}/.espressif/tools/xtensa-esp32-elf/esp-2020r3-8.4.0/xtensa-esp32-elf"
export PATH=$PATH:$ESPRESSIF_TOOLCHAIN_PATH/bin
On Windows:
# on CMD:
set ESPRESSIF_TOOLCHAIN_PATH=%USERPROFILE%\.espressif\tools\xtensa-esp32-elf\esp-2020r3-8.4.0\xtensa-esp32-elf
set ZEPHYR_TOOLCHAIN_VARIANT=espressif
set PATH=%PATH%;%ESPRESSIF_TOOLCHAIN_PATH%\bin
# on PowerShell
$env:ESPRESSIF_TOOLCHAIN_PATH="$env:USERPROFILE\.espressif\tools\xtensa-esp32-elf\esp-2020r3-8.4.0\xtensa-esp32-elf"
$env:ZEPHYR_TOOLCHAIN_VARIANT="espressif"
$env:Path += "$env:ESPRESSIF_TOOLCHAIN_PATH\bin"
Finally, retrieve required submodules to build this port. This might take a while for the first time:
west espressif update
Note
It is recommended running the command above after west update
so that submodules also get updated.
Flashing¶
The usual flash
target will work with the esp32
board
configuration. Here is an example for the Hello World
application.
# From the root of the zephyr repository
west build -b esp32 samples/hello_world
west flash
Refer to Building an Application and Run an Application for more details.
It’s impossible to determine which serial port the ESP32 board is
connected to, as it uses a generic RS232-USB converter. The default of
/dev/ttyUSB0
is provided as that’s often the assigned name on a Linux
machine without any other such converters.
The baud rate of 921600bps is recommended. If experiencing issues when flashing, try halving the value a few times (460800, 230400, 115200, etc). It might be necessary to change the flash frequency or the flash mode; please refer to the esptool documentation for guidance on these settings.
All flashing options are now handled by the West (Zephyr’s meta-tool) tool, including flashing
with custom options such as a different serial port. The west
tool supports
specific options for the ESP32 board, as listed here:
- --esp-idf-path ESP_IDF_PATH
path to ESP-IDF
- --esp-device ESP_DEVICE
serial port to flash, default /dev/ttyUSB0
- --esp-baud-rate ESP_BAUD_RATE
serial baud rate, default 921600
- --esp-flash-size ESP_FLASH_SIZE
flash size, default “detect”
- --esp-flash-freq ESP_FLASH_FREQ
flash frequency, default “40m”
- --esp-flash-mode ESP_FLASH_MODE
flash mode, default “dio”
- --esp-tool ESP_TOOL
if given, complete path to espidf. default is to search for it in [ESP_IDF_PATH]/components/esptool_py/ esptool/esptool.py
- --esp-flash-bootloader ESP_FLASH_BOOTLOADER
Bootloader image to flash
- --esp-flash-partition_table ESP_FLASH_PARTITION_TABLE
Partition table to flash
For example, to flash to /dev/ttyUSB2
, use the following command after
having build the application in the build
directory:
west flash -d build/ --skip-rebuild --esp-device /dev/ttyUSB2
Using JTAG¶
As with much custom hardware, the ESP-32 modules require patches to
OpenOCD that are not upstream. Espressif maintains their own fork of
the project here. By convention they put it in ~/esp
next to the
installations of their toolchain and SDK:
cd ~/esp
git clone https://github.com/espressif/openocd-esp32
cd openocd-esp32
./bootstrap
./configure
make
On the ESP-WROVER-KIT board, the JTAG pins are connected internally to a USB serial port on the same device as the console. These boards require no external hardware and are debuggable as-is. The JTAG signals, however, must be jumpered closed to connect the internal controller (the default is to leave them disconnected). The jumper headers are on the right side of the board as viewed from the power switch, next to similar headers for SPI and UART. See ESP-WROVER-32 V3 Getting Started Guide for details.
On the ESP-WROOM-32 DevKitC board, the JTAG pins are not run to a standard connector (e.g. ARM 20-pin) and need to be manually connected to the external programmer (e.g. a Flyswatter2):
ESP32 pin |
JTAG pin |
---|---|
3V3 |
VTRef |
EN |
nTRST |
IO14 |
TMS |
IO12 |
TDI |
GND |
GND |
IO13 |
TCK |
IO15 |
TDO |
Once the device is connected, you should be able to connect with (for a DevKitC board, replace with esp32-wrover.cfg for WROVER):
cd ~/esp/openocd-esp32
src/openocd -f interface/ftdi/flyswatter2.cfg -c 'set ESP32_ONLYCPU 1' -c 'set ESP32_RTOS none' -f board/esp-wroom-32.cfg -s tcl
The ESP32_ONLYCPU setting is critical: without it OpenOCD will present only the “APP_CPU” via the gdbserver, and not the “PRO_CPU” on which Zephyr is running. It’s currently unexplored as to whether the CPU can be switched at runtime or if breakpoints can be set for either/both.
Now you can connect to openocd with gdb and point it to the OpenOCD gdbserver running (by default) on localhost port 3333. Note that you must use the gdb distributed with the ESP-32 SDK. Builds off of the FSF mainline get inexplicable protocol errors when connecting.
~/esp/xtensa-esp32-elf/bin/xtensa-esp32-elf-gdb outdir/esp32/zephyr.elf
(gdb) target remote localhost:3333
Further documentation can be obtained from the SoC vendor in JTAG debugging for ESP32.