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Fix for issue 3663 by returning early if no scan was started before s… |
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.. | ||
bindings/espidf | ||
boards | ||
certificates | ||
common-hal | ||
esp-idf@d06744f5ef | ||
esp-idf-config | ||
modules | ||
peripherals | ||
supervisor | ||
tools | ||
.gitignore | ||
background.c | ||
background.h | ||
CMakeLists.txt | ||
esp32s2_peripherals_config.h | ||
fatfs_port.c | ||
Makefile | ||
mpconfigport.h | ||
mpconfigport.mk | ||
mphalport.c | ||
mphalport.h | ||
qstrdefsport.h | ||
README.md |
Circuitpython on ESP32-S2
This port adds the ESP32-S2 line of modules from Espressif to Circuitpython. ESP32-S2 modules are low power, single-core Wi-Fi microcontroller SoCs designed for IoT applications.
How this port is organized:
- bindings/ contains some required bindings to the ESP-IDF for exceptions and memory.
- boards/ contains the configuration files for each development board and breakout available on the port.
- common-hal/ contains the port-specific module implementations, used by shared-module and shared-bindings.
- esp-idf/ contains the Espressif IoT development framework installation, includign all the drivers for the port.
- modules/ contains information specific to certain ESP32-S2 hardware modules, such as the pins used for flash and RAM on the WROVER and WROOM.
- peripherals/ contains peripheral setup files and peripheral mapping information, sorted by family and sub-variant. Most files in this directory can be generated with the python scripts in tools/.
- supervisor/ contains port-specific implementations of internal flash, serial and USB, as well as the port.c file, which initializes the port at startup.
- tools/ includes useful python scripts for debugging and other purposes.
At the root level, refer to mpconfigboard.h and mpconfigport.mk for port specific settings and a list of enabled circuitpython modules.
Connecting to the ESP32-S2
The USB port built into ESP32-S2 boards such as the Saola is not the native USB of the board, but a debugging and programming interface. The actual ESP32-S2 native USB which exposes the Circuitpython drive and CDC connection is located on IO pins 19 and 20:
GPIO | USB |
---|---|
20 | D+ (green) |
19 | D- (white) |
GND | GND (black) |
5V | +5V (red) |
Connect these pins using a USB adapter or breakout cable to access the Circuitpython drive.
Building and flashing
Before building or flashing the ESP32-S2, you must install the esp-idf. This must be re-done every time the esp-idf is updated, but not every time you build. Run cd ports/esp32s2
from circuitpython/
to move to the esp32s2 port root, and run:
./esp-idf/install.sh
After this initial installation, you must add the esp-idf tools to your path. You must also do this any time you open a new bash environment for building or flashing:
. esp-idf/export.sh
When Circuitpython updates the ESP-IDF to a new release, you may need to run this installation process again. The exact commands used may also vary based on your bash environment.
Building boards such as the Saola is typically done through make flash
. The default port is tty.SLAB_USBtoUART
, which will only work on certain Mac setups. On most machines, both Mac and Linux, you will need to set the port yourself by running ls /dev/tty.usb*
and selecting the one that only appears when your development board is plugged in. An example make command with the port setting is as follows:
make BOARD=espressif_saola_1_wrover flash PORT=/dev/tty.usbserial-1421120
Debugging
The ESP32-S2 supports JTAG debugging over OpenOCD using a JLink or other probe hardware. The official tutorials can be found on the Espressif website here, but they are mostly for the ESP32-S2 Kaluga, which has built-in debugging.
OpenOCD is automatically installed and added to your bash environment during the esp-idf installation and setup process. You can double check that it is installed by using openocd --version
, as per the tutorial. Attach the JTAG probe pins according to the instructions for JTAG debugging on boards that do not contain an integrated debugger.
Once the debugger is connected physically, you must run OpenOCD with attached configuration files specifying the interface (your debugger probe) and either a target or a board (targets are for SoCs only, and can be used when a full board configuration file doesn't exist). You can find the path location of these files by checking the OPENOCD_SCRIPTS
environmental variable by running echo $OPENOCD_SCRIPTS
in bash. Interfaces will be in the interface/
directory, and targets and boards in the target/
and board/
directories, respectively.
Note: Unfortunately, there are no board files for the esp32-s2 other than the Kaluga, and the included target/esp32s2.cfg
target file will not work by default on the Jlink for boards like the Saola 1, as the default speed is incorrect. In addition, these files are covered under the GPL and cannot be included in Circuitpython. Thus, you must make a copy of the esp32s2.cfg file yourself and add the following line manually, under transport select jtag
at the start of the file:
adapter_khz 1000
Once this is complete, your final OpenOCD command may look something like this:
openocd -f interface/jlink.cfg -f SOMEPATH/copied-esp32s2-saola-1.cfg
Where SOMEPATH
is the location of your copied configuration file (this can be placed in the port/boards director with a prefix to ignore it with .gitignore
, for instance). Interface, target and board config files sourced from espressif only need their paths from the $OPENOCD_SCRIPTS location, you don't need to include their full path. Once OpenOCD is running, connect to GDB with:
xtensa-esp32s2-elf-gdb build-espressif_saola_1_wrover/firmware.elf
And follow the Espressif GDB tutorial instructions for connecting, or add them to your gdbinit
:
target remote :3333
set remote hardware-watchpoint-limit 2
mon reset halt
flushregs
thb app_main
c