STM32F1xx micro-controller C firmware template

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README.md

This firmware template is designed for development boards based around STM32 F4 series micro-controller.

project

summary

describe project purpose

technology

described electronic details

board

The underlying template also supports following board:

WeAct MiniF4, based on a STM32F401CCU6

Which board is used is defined in the Makefile. This is required to map the user LED and button provided on the board

connections

Connect the peripherals the following way (STM32F4xx signal; STM32F4xx pin; peripheral pin; peripheral signal; comment):

list board to peripheral pin connections

DRV8825 stepper motor driver (using one timer for PWM output):

STEP: PA15/TIM2_CH1
DIRECTION: PB15
nSLEEP: PB14, shorted to nRESET
nRESET: PB14, with external 10kOhm pull-down resistor
nENABLE: PB13, with external 10kOhm pull-up resistor
FAULT: PB12, with external 10kOhm pull-up resistor

reed switch:

1: GND
2: PB4

LED driver (using one timer for PWM outputs):

gate 0: PB6/TIM4_CH1
gate 1: PB7/TIM4_CH2
gate 2: PB8/TIM4_CH3
gate 3: PB9/TIM4_CH4

WS2812b LED matrix:

DOUT: PB5 (SPI1_MOSI)

RGB matrix (using one DMA)

DR1: PA2
DG1: PA3
DB1: PA4
DR2: PA5
DG2: PA6
DB2: PA7
CLK: PA0
LAT: PA1
A: PB0
B: PB1
C: PB2
D: PB3
OE: PB10

ESP8266-based ESP-01 (using one UART):

RX: PA9/USART1_TX
TX: PA10/USART1_RX

EN is pulled to VCC using 10 kOhm for the ESP to start. I replaced the 1 MB flash with a 4MB flash to be sure I won't be annoyed by the space limit. I flashed the AT firmware from ESP8266_NONOS_SDK-3.0.5:

esptool.py --chip auto --port /dev/ttyUSB0 --baud 115200 erase_flash
esptool.py -p /dev/ttyUSB0 --chip esp8266 write_flash -fm dio -ff 26m --flash_size 2MB-c1 0x00000 ./bin/boot_v1.7.bin 0x01000 ./bin/at/1024+1024/user1.2048.new.5.bin 0x1fc000 ./bin/esp_init_data_default_v08.bin 0xfe000 ./bin/blank.bin 0x1fe000 ./bin/blank.bin 0x1fb000 ./bin/blank.bin

to test the firmware, issue AT commands:

picocom -b 115200 /dev/ttyUSB0 --omap crcrlf
AT

OK

AT+GMR
version information

configure the access point in flash:

# set station mode
AT+CWMODE_DEF=1
# set AP credentials
AT+CWJAP_DEF="essid","password"

free:

PB4, PB5
PA8/TIM1_CH1

used:

PA12: USB DP
PA11: USB DM
PC13: LED
PC14/PC15: 32kHz XTAL

All pins are configured using defines in the corresponding source code.

code

dependencies

The source code uses the libopencm3 library. The projects is already a git submodules. It will be initialized when compiling the firmware. Alternatively you can run once: git submodule init and git submodule update.

firmware

To compile the firmware run rake.

documentation

To generate doxygen documentation run rake doc.

flash

There are two firmware images: bootloader and application. The bootloader image allows to flash the application over USB using the DFU protocol. The bootloader is started first and immediately jumps to the application if it is valid and the DFU mode is not forced (i.e. by pressing the user button on the board or requesting a DFU detach in the application). The application image is the main application and is implemented in application.c. It is up to the application to advertise USB DFU support (i.e. as does the provided USB CDC ACM example).

The simplest way do flash the bootloader image is using the embedded bootloader. By pressing the BOOT0 button (setting the pin low) while powering or resetting the device, the micro-controller boot its embedded UART/USB DFU bootloader. Connect a USB cable and run rake dfu_bootloader.

Once the bootloader is flashed, it is possible to flash the application over USB using the DFU protocol by running rake flash (equivalent to rake dfu_application. To force the bootloader to start the DFU mode press the user button or short a pin, depending on the board. Note: I use my own DFU bootloader instead of the embedded bootloader because I was not able to start the embedded USB DFU bootloader from the application.

The images can also be flash using SWD (Serial Wire Debug) in case the firmware gets stuck and does not provide USB functionalities. For that you need an SWD adapter. The Makefile uses a ST-Link V2 programmer along OpenOCD software (default), or Black Magic Probe. To flash the bootloader using SWD run rake swd_bootloader (this will also erase the application). To flash the application using SWD run rake swd_application (or rake swd). To erase all memory and unlock read/write protection, run rake remove_protection.

debug

SWD also allows to debug the code running on the micro-controller using GDB. To start the debugging session run rake debug.

USB

The firmware offers serial communication over USART1 and USB (using the CDC ACM device class).