ESP32-C3/MicroPython BLE UART Communication

In my form posts:
~ MicroPython bluetooth (BLE) exampls, run on ESP32-C3 show steps to run MicroPython BLE examples, with example of dummy BLE UART example.
~ MicroPython/ESP32-C3 Exercise: send/receive command via BLE UART modified to send command via UART to control onboard RGB LED remotely.

In this post, it's modified to implement bi-direction BLE UART communication, user enter text, and display on I2C SSD1306 OLED.

For the OLED, read the post ESP32-C3/MicroPython + SSD1306 I2C OLED.

- Once Central connected to Peripheral (both onboard RGB LED ON), user enter text in REPL.
- Central send the text to Peripheral via BLE UART.
- In Peripheral received the text, display on SSD1306 and echo back to Central via BLE UART.
- Central received the text, display on SSD1306.

mpyESP-C3-32S-Kit_ble_simple_peripheral_UART_ssd1306.py

"""
MicroPython/AI-Thinker NodeMCU ESP-C3-32S-Kit
BLE UART Exercise, act as peripheral,
with 128x64 I2C SSD1306 OLED.

Connection between:
ESP32-C3   I2C SSD1306 OLED
============================
GND        GND
3V3        VCC
18         SCL
19         SDA


modified from ble_simple_peripheral.py
"""

# This example demonstrates a UART periperhal.

import bluetooth
import random
import struct
import time
from ble_advertising import advertising_payload

from micropython import const

from machine import Pin, I2C, PWM
import ssd1306

# NodeMCU ESP-C3-32S-Kit onboard LEDs assignment
pwmR = PWM(Pin(3))
pwmG = PWM(Pin(4))
pwmB = PWM(Pin(5))

# set PWM frequency from 1Hz to 40MHz
pwmR.freq(1000)
pwmG.freq(1000)
pwmB.freq(1000)

_IRQ_CENTRAL_CONNECT = const(1)
_IRQ_CENTRAL_DISCONNECT = const(2)
_IRQ_GATTS_WRITE = const(3)

_FLAG_READ = const(0x0002)
_FLAG_WRITE_NO_RESPONSE = const(0x0004)
_FLAG_WRITE = const(0x0008)
_FLAG_NOTIFY = const(0x0010)

_UART_UUID = bluetooth.UUID(
    "6E400001-B5A3-F393-E0A9-E50E24DCCA9E")
_UART_TX = (bluetooth.UUID(
    "6E400003-B5A3-F393-E0A9-E50E24DCCA9E"),
    _FLAG_READ | _FLAG_NOTIFY,
)
_UART_RX = (bluetooth.UUID(
    "6E400002-B5A3-F393-E0A9-E50E24DCCA9E"),
    _FLAG_WRITE | _FLAG_WRITE_NO_RESPONSE,
)
_UART_SERVICE = (
    _UART_UUID,
    (_UART_TX, _UART_RX),
)


class BLESimplePeripheral:
    def __init__(self, ble, name="mpy-uart"):
        self._ble = ble
        self._ble.active(True)
        self._ble.irq(self._irq)
        ((self._handle_tx, self._handle_rx),) \
                           = self._ble.gatts_register_services(
                               (_UART_SERVICE,))
        self._connections = set()
        self._write_callback = None
        self._payload = advertising_payload(
            name=name, services=[_UART_UUID])
        self._advertise()

    def _irq(self, event, data):
        # Track connections so we can send notifications.
        if event == _IRQ_CENTRAL_CONNECT:
            conn_handle, _, _ = data
            print("New connection", conn_handle)
            self._connections.add(conn_handle)
            
            #turn ON GREEN LED
            pwmG.duty(10)
            
            oled_ssd1306.fill(0)    #clear screen
            oled_ssd1306.text("Connected", 0, 0 , 1)
            oled_ssd1306.show()
        elif event == _IRQ_CENTRAL_DISCONNECT:
            conn_handle, _, _ = data
            print("Disconnected", conn_handle)
            self._connections.remove(conn_handle)
            # Start advertising again to allow a new connection.
            self._advertise()
            
            #turn OFF GREEN LED
            pwmG.duty(0)
            
            oled_ssd1306.fill(0)    #clear screen
            oled_ssd1306.text("Disconnected", 0, 0 , 1)
            oled_ssd1306.show()
        elif event == _IRQ_GATTS_WRITE:
            conn_handle, value_handle = data
            value = self._ble.gatts_read(value_handle)
            if (value_handle == self._handle_rx
                and self._write_callback):
                self._write_callback(value)

    def send(self, data):
        for conn_handle in self._connections:
            self._ble.gatts_notify(
                conn_handle, self._handle_tx, data)

    def is_connected(self):
        return len(self._connections) > 0

    def _advertise(self, interval_us=500000):
        print("Starting advertising")
        self._ble.gap_advertise(
            interval_us, adv_data=self._payload)

    def on_write(self, callback):
        self._write_callback = callback


def demo():
    ble = bluetooth.BLE()
    p = BLESimplePeripheral(ble)

    def on_rx(v):
        print("RX", v)
        
        oled_ssd1306.scroll(0,-10)
        oled_ssd1306.fill_rect(0, 50,
                               oled_ssd1306.width-1, 10,
                               0)
        oled_ssd1306.text(v, 0, 50 , 1)
        oled_ssd1306.show()
        
        # echo back in upper case
        p.send(v.upper())
        
    p.on_write(on_rx)

    i = 0
    while True:
        pass
#        if p.is_connected():
#            # Short burst of queued notifications.
#            for _ in range(3):
#                data = str(i) + "_"
#                print("TX", data)
#                p.send(data)
#                i += 1
#        time.sleep_ms(100)

if __name__ == "__main__":
    #All OFF all onboard LED
    pwmR.duty(0)
    pwmG.duty(0)
    pwmB.duty(0)
    
    oled_i2c = I2C(0)
    print("Default I2C:", oled_i2c, "\n")
    
    try:
        oled_ssd1306 = ssd1306.SSD1306_I2C(128, 64, oled_i2c)
        print("Default SSD1306 I2C address:",
              oled_ssd1306.addr, "/",
              hex(oled_ssd1306.addr))
        oled_ssd1306.text('ESP32C3 BLE UART', 0, 0, 1)
        oled_ssd1306.text('Peripheral', 0, 10, 1)
        oled_ssd1306.show()
    except OSError as exc:
        print("OSError!", exc)
        if exc.errno == errno.ENODEV:
            print("No such device")


    demo()

mpyESP32-C3-DevKitM-1_ble_simple_central_UART_128x32.py

"""
MicroPython/Espressif ESP32-C3-DevKitM-1
BLE UART Exercise, act as central,
with 128x32 I2C SSD1306 OLED.

Connection between:
ESP32-C3   I2C SSD1306 OLED
============================
GND        GND
3V3        VCC
18         SCL
19         SDA
"""

# This example finds and connects to a peripheral running the
# UART service (e.g. ble_simple_peripheral.py).

import bluetooth
#import random
#import struct
import time

from ble_advertising import decode_services, decode_name

from micropython import const
from neopixel import NeoPixel
import _thread

from machine import Pin, I2C
import ssd1306

# On Espreffif ESP32-C3-DevKitM-1:
# The onboard RGB LED (WS2812) is connected to GPIO8

np = NeoPixel(Pin(8), 1)

rqs_to_send =False
to_send = ""

_IRQ_CENTRAL_CONNECT = const(1)
_IRQ_CENTRAL_DISCONNECT = const(2)
_IRQ_GATTS_WRITE = const(3)
_IRQ_GATTS_READ_REQUEST = const(4)
_IRQ_SCAN_RESULT = const(5)
_IRQ_SCAN_DONE = const(6)
_IRQ_PERIPHERAL_CONNECT = const(7)
_IRQ_PERIPHERAL_DISCONNECT = const(8)
_IRQ_GATTC_SERVICE_RESULT = const(9)
_IRQ_GATTC_SERVICE_DONE = const(10)
_IRQ_GATTC_CHARACTERISTIC_RESULT = const(11)
_IRQ_GATTC_CHARACTERISTIC_DONE = const(12)
_IRQ_GATTC_DESCRIPTOR_RESULT = const(13)
_IRQ_GATTC_DESCRIPTOR_DONE = const(14)
_IRQ_GATTC_READ_RESULT = const(15)
_IRQ_GATTC_READ_DONE = const(16)
_IRQ_GATTC_WRITE_DONE = const(17)
_IRQ_GATTC_NOTIFY = const(18)
_IRQ_GATTC_INDICATE = const(19)

_ADV_IND = const(0x00)
_ADV_DIRECT_IND = const(0x01)
_ADV_SCAN_IND = const(0x02)
_ADV_NONCONN_IND = const(0x03)

_UART_SERVICE_UUID = bluetooth.UUID(
    "6E400001-B5A3-F393-E0A9-E50E24DCCA9E")
_UART_RX_CHAR_UUID = bluetooth.UUID(
    "6E400002-B5A3-F393-E0A9-E50E24DCCA9E")
_UART_TX_CHAR_UUID = bluetooth.UUID(
    "6E400003-B5A3-F393-E0A9-E50E24DCCA9E")


class BLESimpleCentral:
    def __init__(self, ble):
        self._ble = ble
        self._ble.active(True)
        self._ble.irq(self._irq)

        self._reset()

    def _reset(self):
        # Cached name and address from a successful scan.
        self._name = None
        self._addr_type = None
        self._addr = None

        # Callbacks for completion of various operations.
        # These reset back to None after being invoked.
        self._scan_callback = None
        self._conn_callback = None
        self._read_callback = None

        # Persistent callback for when
        # new data is notified from the device.
        self._notify_callback = None

        # Connected device.
        self._conn_handle = None
        self._start_handle = None
        self._end_handle = None
        self._tx_handle = None
        self._rx_handle = None

    def _irq(self, event, data):
        if event == _IRQ_SCAN_RESULT:
            addr_type, addr, adv_type, rssi, adv_data = data
            if (adv_type in (_ADV_IND, _ADV_DIRECT_IND)
                and
                _UART_SERVICE_UUID in decode_services(adv_data)):
                # Found a potential device,
                # remember it and stop scanning.
                self._addr_type = addr_type
                self._addr = bytes(
                    addr
                )  # Note: addr buffer is owned by
                   #       caller so need to copy it.
                self._name = decode_name(adv_data) or "?"
                self._ble.gap_scan(None)

        elif event == _IRQ_SCAN_DONE:
            if self._scan_callback:
                if self._addr:
                    # Found a device during the scan
                    # (and the scan was explicitly stopped).
                    self._scan_callback(
                        self._addr_type, self._addr, self._name)
                    self._scan_callback = None
                else:
                    # Scan timed out.
                    self._scan_callback(None, None, None)

        elif event == _IRQ_PERIPHERAL_CONNECT:
            # Connect successful.
            conn_handle, addr_type, addr = data
            if addr_type == self._addr_type and addr == self._addr:
                self._conn_handle = conn_handle
                self._ble.gattc_discover_services(self._conn_handle)

        elif event == _IRQ_PERIPHERAL_DISCONNECT:
            # Disconnect (either initiated by us or the remote end).
            conn_handle, _, _ = data
            if conn_handle == self._conn_handle:
                # If it was initiated by us, it'll already be reset.
                self._reset()

        elif event == _IRQ_GATTC_SERVICE_RESULT:
            # Connected device returned a service.
            conn_handle, start_handle, end_handle, uuid = data
            print("service", data)
            if (conn_handle == self._conn_handle
                and
                uuid == _UART_SERVICE_UUID):
                self._start_handle, self._end_handle \
                                    = start_handle, end_handle

        elif event == _IRQ_GATTC_SERVICE_DONE:
            # Service query complete.
            if self._start_handle and self._end_handle:
                self._ble.gattc_discover_characteristics(
                    self._conn_handle,
                    self._start_handle,
                    self._end_handle)
            else:
                print("Failed to find uart service.")

        elif event == _IRQ_GATTC_CHARACTERISTIC_RESULT:
            # Connected device returned a characteristic.
            conn_handle, def_handle, value_handle, properties, uuid = data
            if (conn_handle == self._conn_handle
                and
                uuid == _UART_RX_CHAR_UUID):
                self._rx_handle = value_handle
            if (conn_handle == self._conn_handle
                and
                uuid == _UART_TX_CHAR_UUID):
                self._tx_handle = value_handle

        elif event == _IRQ_GATTC_CHARACTERISTIC_DONE:
            # Characteristic query complete.
            if (self._tx_handle is not None
                and
                self._rx_handle is not None):
                # We've finished connecting and
                # discovering device, fire the connect callback.
                if self._conn_callback:
                    self._conn_callback()
            else:
                print("Failed to find uart rx characteristic.")

        elif event == _IRQ_GATTC_WRITE_DONE:
            conn_handle, value_handle, status = data
            print("TX complete")

        elif event == _IRQ_GATTC_NOTIFY:
            conn_handle, value_handle, notify_data = data
            if (conn_handle == self._conn_handle
                and
                value_handle == self._tx_handle):
                if self._notify_callback:
                    self._notify_callback(notify_data)

    # Returns true if we've successfully connected
    # and discovered characteristics.
    def is_connected(self):
        return (
            self._conn_handle is not None
            and self._tx_handle is not None
            and self._rx_handle is not None
        )

    # Find a device advertising the environmental
    # sensor service.
    def scan(self, callback=None):
        self._addr_type = None
        self._addr = None
        self._scan_callback = callback
        self._ble.gap_scan(2000, 30000, 30000)

    # Connect to the specified device (otherwise
    # use cached address from a scan).
    def connect(self, addr_type=None, addr=None, callback=None):
        self._addr_type = addr_type or self._addr_type
        self._addr = addr or self._addr
        self._conn_callback = callback
        if self._addr_type is None or self._addr is None:
            return False
        self._ble.gap_connect(self._addr_type, self._addr)
        return True

    # Disconnect from current device.
    def disconnect(self):
        if not self._conn_handle:
            return
        self._ble.gap_disconnect(self._conn_handle)
        self._reset()

    # Send data over the UART
    def write(self, v, response=False):
        if not self.is_connected():
            return
        self._ble.gattc_write(self._conn_handle,
                              self._rx_handle,
                              v,
                              1 if response else 0)

    # Set handler for when data is received over the UART.
    def on_notify(self, callback):
        self._notify_callback = callback

def demo():
    global rqs_to_send
    global to_send
    
    ble = bluetooth.BLE()
    central = BLESimpleCentral(ble)

    not_found = False
    
    #Turn ON onboard RGB BLUE
    np[0] = (0, 0, 10)
    np.write()
    
    def on_scan(addr_type, addr, name):
        if addr_type is not None:
            print("Found peripheral:",
                  addr_type, addr, name)
            central.connect()
        else:
            nonlocal not_found
            not_found = True
            print("No peripheral found.")
            
            #Turn ON onboard RGB BLUE
            np[0] = (10, 0, 0)
            np.write()

    central.scan(callback=on_scan)

    # Wait for connection...
    while not central.is_connected():
        time.sleep_ms(100)
        if not_found:
            return

    #Turn ON onboard RGB GREEN
    np[0] = (0, 10, 0)
    np.write()
    
    oled_ssd1306.fill(0)    #clear screen
    oled_ssd1306.text("Connected", 0, 0 , 1)
    oled_ssd1306.show()
            
    print("Connected")
    print("Enter anything to send")
    
    rqs_to_send = False  # clear previous request

    def on_rx(v):
        # convert memoryview to str
        v_str = str(v,'utf8')
        print("RX", v, " : ", v_str)
        
        oled_ssd1306.scroll(0,-10)
        oled_ssd1306.fill_rect(0, 20,
                               oled_ssd1306.width-1, 10,
                               0)
        oled_ssd1306.text(v_str, 0, 20 , 1)
        oled_ssd1306.show()

    central.on_notify(on_rx)

    with_response = False

#    i = 0
    while central.is_connected():
    
        if rqs_to_send:
            central.write(to_send, with_response)
            rqs_to_send = False
            
#        try:
#            v = str(i) + "_"
#            print("TX", v)
#            central.write(v, with_response)
#        except:
#            print("TX failed")
#        i += 1
#       time.sleep_ms(400 if with_response else 30)

    #Turn OFF onboard RGB
    np[0] = (0, 0, 0)
    np.write()
    
    oled_ssd1306.fill(0)    #clear screen
    oled_ssd1306.text("Disconnected", 0, 0 , 1)
    oled_ssd1306.show()
    
    print("Disconnected")


if __name__ == "__main__":
    
    #All OFF all onboard RGB
    np[0] = (0, 0, 0)
    np.write()
    
    oled_i2c = I2C(0)
    print("Default I2C:", oled_i2c, "\n")
    
    try:
        oled_ssd1306 = ssd1306.SSD1306_I2C(128, 32, oled_i2c)
        print("Default SSD1306 I2C address:",
              oled_ssd1306.addr, "/",
              hex(oled_ssd1306.addr))
        oled_ssd1306.text('ESP32C3 BLE UART', 0, 0, 1)
        oled_ssd1306.text('Central', 0, 10, 1)
        oled_ssd1306.show()
    except OSError as exc:
        print("OSError!", exc)
        if exc.errno == errno.ENODEV:
            print("No such device")
    
    def input_thread():
        global rqs_to_send
        global to_send
        while True:
            time.sleep(0.1)
            to_send = input()
            rqs_to_send = True
    
    # In my trial:
    # Without call _thread.stack_size(32768) will easy
    # to force reboot by:
    # ***ERROR*** A stack overflow in task mp_thread has been detected.
    _thread.stack_size(32768)
    _thread.start_new_thread(input_thread, ())
    
    demo()

ESP32-C3/MicroPython multithreading exercise, get user input un-blocked using _thread.

This exercise get user input by call input(). But input() is a blocking function, means it blocks further execution of a program until user enter something. In this exercise code, read user input by calling input() and control RGB in two separated thread using _thread.

Please notice that _thread currently is highly experimental and its API is not yet fully settled.

mpyC3_thread.py

"""
ESP32-C3/MicroPython exercise:
read user input non-blocked using _thread

MicroPython libraries _thread (multithreading support)
https://docs.micropython.org/en/latest/library/_thread.html

This module is highly experimental and its API is not yet fully
settled and not yet described in documentation.

So, basically - the excise is by guessing, and run as is.

Tested on Espressif ESP32-C3-DevKitM-1/micropython v1.19.1
"""
import os
import sys
import time
import _thread
import neopixel
from machine import Pin

# On Espreffif ESP32-C3-DevKitM-1:
# The onboard RGB LED (WS2812) is connected to GPIO8
np = neopixel.NeoPixel(Pin(8), 1)

rqs_to_show =False
to_show = ""

print()

print("====================================")
print(sys.implementation[0], os.uname()[3],
      "\nrun on", os.uname()[4])
print("====================================")

# thread to read user input,
# input() will block the program,
# so have to run in another thread.
def input_thread():
    global rqs_to_show
    global to_show
    while True:
        user_input = input()
        to_show = user_input
        rqs_to_show = True
        print("in input_thread() => ", user_input)
        
# thread to change RGB repeatly.
def rgb_thread():
    while True:
        np[0] = (10, 0, 0)
        np.write()
        time.sleep(0.5)
        np[0] = (0, 10, 0)
        np.write()
        time.sleep(0.5)
        np[0] = (0, 0, 10)
        np.write()
        time.sleep(0.5)

_thread.start_new_thread(input_thread, ())
_thread.start_new_thread(rgb_thread, ())

while True:
    if rqs_to_show:
        rqs_to_show = False
        print("in main thread: rqs_to_show -> ", to_show)

Next:
~ applied on real exercise: ESP32-C3/MicroPython BLE UART Communication

MicroPython/ESP32-C3 Exercise: send/receive command via BLE UART

My former post show steps to MicroPython bluetooth (BLE) exampls, run on ESP32-C3. It's modified to send and receive command to control onboard LED remotely.

ble_simple_peripheral_LED.py (modified from ble_simple_peripheral.py) run on AI-Thinker NodeMCU ESP-C3-32S-Kit, act to be BLE Peripheral.

ble_simple_central_button.py (modified from ble_simple_central.py) run on Espressif ESP32-C3-DevKitM-1, act to be BLE Central.

Both flashed with MicroPython v1.19.1 frameware. ble_advertising.py have to be saved on both central/peripheral MicroPython device.

Once connected, user pressed central's onboard button to send command to peripheral via BLE UART, to toggle peripheral onboard LED.

In peripheral side, turn ON/OFF onboard LED according to received command, and send back the command to central, to control central's onboard LED. 

Once central receive command, turn ON/OFF onboard LED accordingly.

related:
~ MicroPython/NodeMCU ESP-C3-32S-Kit to control onboard LEDs
~ MicroPython/ESP32-C3-DevKitM-1 exercise: onboard BOOT button, and RGB LED (Neopixel)

ble_simple_peripheral_LED.py

"""
MicroPython(v1.19.1) exercise
run on AI-Thinker NodeMCU ESP-C3-32S-Kit
act as BLE UART periperhal.

Receive command from central, turn on/off onboard LED,
and send back the command to central.

Modified from MicroPython ble_simple_peripheral.py example
https://github.com/micropython/micropython/
blob/master/examples/bluetooth/ble_simple_central.py

"""

# This example demonstrates a UART periperhal.

import bluetooth
import random
import struct
import time
from ble_advertising import advertising_payload
from machine import Pin

from micropython import const

CMD_LEDON = b'LEDON\r\n'
CMD_LEDOFF = b'LEDOFF\r\n'

# NodeMCU ESP-C3-32S-Kit onboard LEDs assignment
pinR = Pin(3, Pin.OUT)
pinG = Pin(4, Pin.OUT)
pinB = Pin(5, Pin.OUT)

_IRQ_CENTRAL_CONNECT = const(1)
_IRQ_CENTRAL_DISCONNECT = const(2)
_IRQ_GATTS_WRITE = const(3)

_FLAG_READ = const(0x0002)
_FLAG_WRITE_NO_RESPONSE = const(0x0004)
_FLAG_WRITE = const(0x0008)
_FLAG_NOTIFY = const(0x0010)

_UART_UUID = bluetooth.UUID(
    "6E400001-B5A3-F393-E0A9-E50E24DCCA9E")
_UART_TX = (
    bluetooth.UUID(
        "6E400003-B5A3-F393-E0A9-E50E24DCCA9E"),
    _FLAG_READ | _FLAG_NOTIFY,
)
_UART_RX = (
    bluetooth.UUID(
        "6E400002-B5A3-F393-E0A9-E50E24DCCA9E"),
    _FLAG_WRITE | _FLAG_WRITE_NO_RESPONSE,
)
_UART_SERVICE = (
    _UART_UUID,
    (_UART_TX, _UART_RX),
)


class BLESimplePeripheral:
    def __init__(self, ble, name="mpy-uart"):
        self._ble = ble
        self._ble.active(True)
        self._ble.irq(self._irq)
        ((self._handle_tx,
          self._handle_rx),) \
          = self._ble.gatts_register_services(
              (_UART_SERVICE,))
        self._connections = set()
        self._write_callback = None
        self._payload = \
                      advertising_payload(
                          name=name, services=[_UART_UUID])
        self._advertise()

    def _irq(self, event, data):
        # Track connections so we can send notifications.
        if event == _IRQ_CENTRAL_CONNECT:
            conn_handle, _, _ = data
            print("New connection", conn_handle)
            self._connections.add(conn_handle)
        elif event == _IRQ_CENTRAL_DISCONNECT:
            conn_handle, _, _ = data
            print("Disconnected", conn_handle)
            self._connections.remove(conn_handle)
            # Start advertising again to allow a new connection.
            self._advertise()
        elif event == _IRQ_GATTS_WRITE:
            conn_handle, value_handle = data
            value = self._ble.gatts_read(value_handle)
            if (value_handle == self._handle_rx and
                self._write_callback):
                self._write_callback(value)

    def send(self, data):
        for conn_handle in self._connections:
            self._ble.gatts_notify(conn_handle,
                                   self._handle_tx,
                                   data)

    def is_connected(self):
        return len(self._connections) > 0

    def _advertise(self, interval_us=500000):
        print("Starting advertising")
        self._ble.gap_advertise(interval_us,
                                adv_data=self._payload)

    def on_write(self, callback):
        self._write_callback = callback

def Turn_LED(val):
    pinR.value(val)
    pinG.value(val)
    pinB.value(val)

def demo():
    ble = bluetooth.BLE()
    p = BLESimplePeripheral(ble)

    def on_rx(v):
        # command received from central,
        # turn ON/OFF LED accoringly,
        # and send back the command to centrol.
        print("RX", v)
        
        if v == CMD_LEDON:
            Turn_LED(1)
            print("command received: ", CMD_LEDON)
            p.send("from peripheral:")
            p.send(CMD_LEDON)
        elif v == CMD_LEDOFF:
            Turn_LED(0)
            print("command received: ", CMD_LEDOFF)
            p.send("from peripheral:")
            p.send(CMD_LEDOFF)

    p.on_write(on_rx)

    i = 0
    while True:
        """
        if p.is_connected():
            # Short burst of queued notifications.
            for _ in range(3):
                data = str(i) + "_"
                print("TX", data)
                p.send(data)
                i += 1
        """
        time.sleep_ms(100)


if __name__ == "__main__":
    demo()

ble_simple_central_button.py

"""
MicroPython(v1.19.1) exercise
run on Espressif ESP32-C3-DevKitM-1 
act as BLE UART central.

Detect onboard BOOT button,
send command to peripheral to toggle peripheral onboard LED.
and receive command from peripheral, turn on/off onboard.

* No debouncing for BOOT button detection here.

Modified from MicroPython ble_simple_central.py example
https://github.com/micropython/micropython/
blob/master/examples/bluetooth/ble_simple_peripheral.py

"""

# This example finds and connects to a peripheral running the
# UART service (e.g. ble_simple_peripheral.py).

import bluetooth
import random
import struct
import time
import micropython
import machine
import neopixel

from ble_advertising import decode_services, decode_name

from micropython import const

CMD_LEDON = b'LEDON\r\n'
CMD_LEDOFF = b'LEDOFF\r\n'

button_BOOT = machine.Pin(9,
                          machine.Pin.IN,
                          machine.Pin.PULL_UP)
np = neopixel.NeoPixel(machine.Pin(8), 1)

# To turn OFF peripheral LED in first power-up
current_led_val = True
root_button_pressed = True

# Turn OFF onboard RGB
np[0] = (0, 0, 0)
np.write()

def boot_pressed_handler(pin):
    global root_button_pressed
    root_button_pressed = True
    
button_BOOT.irq(trigger=machine.Pin.IRQ_FALLING,
                handler=boot_pressed_handler)

_IRQ_CENTRAL_CONNECT = const(1)
_IRQ_CENTRAL_DISCONNECT = const(2)
_IRQ_GATTS_WRITE = const(3)
_IRQ_GATTS_READ_REQUEST = const(4)
_IRQ_SCAN_RESULT = const(5)
_IRQ_SCAN_DONE = const(6)
_IRQ_PERIPHERAL_CONNECT = const(7)
_IRQ_PERIPHERAL_DISCONNECT = const(8)
_IRQ_GATTC_SERVICE_RESULT = const(9)
_IRQ_GATTC_SERVICE_DONE = const(10)
_IRQ_GATTC_CHARACTERISTIC_RESULT = const(11)
_IRQ_GATTC_CHARACTERISTIC_DONE = const(12)
_IRQ_GATTC_DESCRIPTOR_RESULT = const(13)
_IRQ_GATTC_DESCRIPTOR_DONE = const(14)
_IRQ_GATTC_READ_RESULT = const(15)
_IRQ_GATTC_READ_DONE = const(16)
_IRQ_GATTC_WRITE_DONE = const(17)
_IRQ_GATTC_NOTIFY = const(18)
_IRQ_GATTC_INDICATE = const(19)

_ADV_IND = const(0x00)
_ADV_DIRECT_IND = const(0x01)
_ADV_SCAN_IND = const(0x02)
_ADV_NONCONN_IND = const(0x03)

_UART_SERVICE_UUID = bluetooth.UUID(
    "6E400001-B5A3-F393-E0A9-E50E24DCCA9E")
_UART_RX_CHAR_UUID = bluetooth.UUID(
    "6E400002-B5A3-F393-E0A9-E50E24DCCA9E")
_UART_TX_CHAR_UUID = bluetooth.UUID(
    "6E400003-B5A3-F393-E0A9-E50E24DCCA9E")


class BLESimpleCentral:
    def __init__(self, ble):
        self._ble = ble
        self._ble.active(True)
        self._ble.irq(self._irq)

        self._reset()

    def _reset(self):
        # Cached name and address from a successful scan.
        self._name = None
        self._addr_type = None
        self._addr = None

        # Callbacks for completion of various operations.
        # These reset back to None after being invoked.
        self._scan_callback = None
        self._conn_callback = None
        self._read_callback = None

        # Persistent callback for when new data is
        # notified from the device.
        self._notify_callback = None

        # Connected device.
        self._conn_handle = None
        self._start_handle = None
        self._end_handle = None
        self._tx_handle = None
        self._rx_handle = None

    def _irq(self, event, data):
        if event == _IRQ_SCAN_RESULT:
            addr_type, addr, adv_type, rssi, adv_data = data
            if (adv_type in (_ADV_IND, _ADV_DIRECT_IND) and
                _UART_SERVICE_UUID in decode_services(adv_data)):
                # Found a potential device, remember it
                # and stop scanning.
                self._addr_type = addr_type
                self._addr = bytes(
                    addr
                )  # Note: addr buffer is owned by caller so
                   # need to copy it.
                self._name = decode_name(adv_data) or "?"
                self._ble.gap_scan(None)

        elif event == _IRQ_SCAN_DONE:
            if self._scan_callback:
                if self._addr:
                    # Found a device during the scan
                    # (and the scan was explicitly stopped).
                    self._scan_callback(self._addr_type,
                                        self._addr,
                                        self._name)
                    self._scan_callback = None
                else:
                    # Scan timed out.
                    self._scan_callback(None, None, None)

        elif event == _IRQ_PERIPHERAL_CONNECT:
            # Connect successful.
            conn_handle, addr_type, addr = data
            if addr_type == self._addr_type and addr == self._addr:
                self._conn_handle = conn_handle
                self._ble.gattc_discover_services(self._conn_handle)

        elif event == _IRQ_PERIPHERAL_DISCONNECT:
            # Disconnect (either initiated by us or the remote end).
            conn_handle, _, _ = data
            if conn_handle == self._conn_handle:
                # If it was initiated by us, it'll already be reset.
                self._reset()

        elif event == _IRQ_GATTC_SERVICE_RESULT:
            # Connected device returned a service.
            conn_handle, start_handle, end_handle, uuid = data
            print("service", data)
            if conn_handle == self._conn_handle and uuid == _UART_SERVICE_UUID:
                self._start_handle, self._end_handle = start_handle, end_handle

        elif event == _IRQ_GATTC_SERVICE_DONE:
            # Service query complete.
            if self._start_handle and self._end_handle:
                self._ble.gattc_discover_characteristics(
                    self._conn_handle,
                    self._start_handle,
                    self._end_handle
                )
            else:
                print("Failed to find uart service.")

        elif event == _IRQ_GATTC_CHARACTERISTIC_RESULT:
            # Connected device returned a characteristic.
            conn_handle, def_handle, value_handle, properties, uuid = data
            if (conn_handle == self._conn_handle and
                uuid == _UART_RX_CHAR_UUID):
                self._rx_handle = value_handle
            if (conn_handle == self._conn_handle and
                uuid == _UART_TX_CHAR_UUID):
                self._tx_handle = value_handle

        elif event == _IRQ_GATTC_CHARACTERISTIC_DONE:
            # Characteristic query complete.
            if self._tx_handle is not None and self._rx_handle is not None:
                # We've finished connecting and discovering device,
                # fire the connect callback.
                if self._conn_callback:
                    self._conn_callback()
            else:
                print("Failed to find uart rx characteristic.")

        elif event == _IRQ_GATTC_WRITE_DONE:
            conn_handle, value_handle, status = data
            print("TX complete")

        elif event == _IRQ_GATTC_NOTIFY:
            conn_handle, value_handle, notify_data = data
            if (conn_handle == self._conn_handle
                and value_handle == self._tx_handle):
                if self._notify_callback:
                    self._notify_callback(notify_data)

    # Returns true if we've successfully connected and
    # discovered characteristics.
    def is_connected(self):
        return (
            self._conn_handle is not None
            and self._tx_handle is not None
            and self._rx_handle is not None
        )

    # Find a device advertising the environmental sensor service.
    def scan(self, callback=None):
        self._addr_type = None
        self._addr = None
        self._scan_callback = callback
        self._ble.gap_scan(2000, 30000, 30000)

    # Connect to the specified device
    # (otherwise use cached address from a scan).
    def connect(self, addr_type=None, addr=None, callback=None):
        self._addr_type = addr_type or self._addr_type
        self._addr = addr or self._addr
        self._conn_callback = callback
        if self._addr_type is None or self._addr is None:
            return False
        self._ble.gap_connect(self._addr_type, self._addr)
        return True

    # Disconnect from current device.
    def disconnect(self):
        if not self._conn_handle:
            return
        self._ble.gap_disconnect(self._conn_handle)
        self._reset()

    # Send data over the UART
    def write(self, v, response=False):
        if not self.is_connected():
            return
        self._ble.gattc_write(self._conn_handle,
                              self._rx_handle, v,
                              1 if response else 0)

    # Set handler for when data is received over the UART.
    def on_notify(self, callback):
        self._notify_callback = callback
    
def demo():
    global root_button_pressed
    global current_led_val
    
    ble = bluetooth.BLE()
    central = BLESimpleCentral(ble)

    not_found = False
    
    def send_CMD(cmd):
        try:
            central.write(cmd, with_response)
        except:
            print("TX failed")

    def on_scan(addr_type, addr, name):
        if addr_type is not None:
            print("Found peripheral:", addr_type, addr, name)
            central.connect()
        else:
            nonlocal not_found
            not_found = True
            print("No peripheral found.")

    central.scan(callback=on_scan)

    # Wait for connection...
    while not central.is_connected():
        time.sleep_ms(100)
        if not_found:
            return

    print("Connected")
    
    def on_rx(v):
        # command received from peripheral,
        # update onboard RGB accordingly.
        print("RX", v)
        
        #convert memoryview to str
        cmd = str(v,'utf8')
        print(cmd)
        
        if v == CMD_LEDON:
            np[0] = (3, 3, 0)
            np.write()
        elif v == CMD_LEDOFF:
            np[0] = (0, 0, 0)
            np.write()
            

    central.on_notify(on_rx)

    with_response = False

    while central.is_connected():
        
        if root_button_pressed:
            # BOOT button pressed,
            # send command to peripheral to toggle LED
            root_button_pressed = False
            current_led_val = not current_led_val
            print("- root_button_pressed -", current_led_val)
            
            if current_led_val:
                send_CMD(CMD_LEDON)
                
            else:
                send_CMD(CMD_LEDOFF)

        time.sleep_ms(400 if with_response else 30)

    print("Disconnected")


if __name__ == "__main__":
    demo()

MicroPython/ESP32-C3-DevKitM-1 exercise: onboard BOOT button, and RGB LED (Neopixel).

Run on Espressif ESP32-C3-DevKitM-1 with MicroPython v1.19.1 on 2022-06-18 installed, the following exercise detect onboard BOOT button, and control onboard RGB LED (Neopixel).


mpyESP32-C3-DevKitM-1_neopixel.py
Simple testing on onboard RGB LED (Neopixel).

import machine
import time
import neopixel

"""
MicroPython v1.19.1/ESP32-C3-DevKitM-1 exercise:
Simple testing on onboard RGB LED (Neopixel).
"""

# On Espreffif ESP32-C3-DevKitM-1:
# The onboard RGB LED (WS2812) is connected to GPIO8

np = neopixel.NeoPixel(machine.Pin(8), 1)

while True:
    np[0] = (0, 0, 0)
    np.write()
    time.sleep(1)
    np[0] = (255, 0, 0)
    np.write()
    time.sleep(1)
    np[0] = (0, 255, 0)
    np.write()
    time.sleep(1)
    np[0] = (0, 0, 255)
    np.write()
    time.sleep(1)
    np[0] = (255, 255, 255)
    np.write()
    time.sleep(1)
    

mpyESP32-C3-DevKitM-1_neopixel_2.py
Control onboard RGB LED (Neopixel), with level control.

import machine
import time
import neopixel

"""
MicroPython v1.19.1/ESP32-C3-DevKitM-1 exercise:
Control onboard RGB LED (Neopixel), with level control.
"""

# On Espreffif ESP32-C3-DevKitM-1:
# The onboard RGB LED (WS2812) is connected to GPIO8

np = neopixel.NeoPixel(machine.Pin(8), 1)

def setNeoPixel(level, enable):
    np[0] = (level * enable[0],
             level * enable[1],
             level * enable[2])
    np.write()
    
def testNeoPixel(enable):
    for l in range(0, 256):
        setNeoPixel(l, enable)
        time.sleep(0.02)

while True:
    np[0] = (0, 0, 0)
    np.write()
    time.sleep(1)

    testNeoPixel([True, False, False])
    testNeoPixel([False, True, False])
    testNeoPixel([False, False, True])
    
    testNeoPixel([True, True, False])
    testNeoPixel([False, True, True])
    testNeoPixel([True, False, True])
    
    testNeoPixel([True, True, True])

mpyESP32-C3-DevKitM-1_button.py
Simple test onboard BOOT button, and verify the logic.

import machine
import time

"""
MicroPython v1.19.1/ESP32-C3-DevKitM-1 exercise:
Simple test onboard BOOT button, and verify the logic.
"""

# On Espreffif ESP32-C3-DevKitM-1:
# The onboard BOOT Button is connected to GPIO9

button_BOOT = machine.Pin(9,
                          machine.Pin.IN,
                          machine.Pin.PULL_UP)

while True:
    time.sleep(0.5)
    print(button_BOOT.value())

mpyESP32-C3-DevKitM-1_button_neopixel.py
Read BOOT button and turn on/off onboard RGB accordingly.

import machine
import time
import neopixel

"""
MicroPython v1.19.1/ESP32-C3-DevKitM-1 exercise:
Read BOOT button and turn on/off onboard RGB accordingly.
"""

# On Espreffif ESP32-C3-DevKitM-1:
# The onboard RGB LED (WS2812) is connected to GPIO8
# The onboard BOOT Button is connected to GPIO9

button_BOOT = machine.Pin(9,
                          machine.Pin.IN,
                          machine.Pin.PULL_UP)
np = neopixel.NeoPixel(machine.Pin(8), 1)

while True:
    time.sleep(0.2)
    if (button_BOOT.value()):  # button released
        np[0] = (0, 0, 0)
    else:                      # button pressed
        np[0] = (0, 3, 0)
    np.write()

mpyESP32-C3-DevKitM-1_button_irq.py
Implement IRQ handler to detect BOOT button pressing, and toggle onboard RGB.

import machine
import time
import neopixel

"""
MicroPython v1.19.1/ESP32-C3-DevKitM-1 exercise:
Implement IRQ handler to detect BOOT button pressing,
and toggle onboard RGB.

* No debouncing for button detection here.
"""

# On Espreffif ESP32-C3-DevKitM-1:
# The onboard RGB LED (WS2812) is connected to GPIO8
# The onboard BOOT Button is connected to GPIO9

button_BOOT = machine.Pin(9,
                          machine.Pin.IN,
                          machine.Pin.PULL_UP)
np = neopixel.NeoPixel(machine.Pin(8), 1)

np[0] = (0, 0, 0)
last_np_state = False
def toggle_LED():
    global last_np_state
    last_np_state =  not last_np_state

    if last_np_state:
        np[0] = (0, 0, 5)
    else:
        np[0] = (0, 0, 0)
    np.write()
    
def boot_pressed_handler(pin):
    print("BOOT button pressed:\t", pin)
    toggle_LED()
    
button_BOOT.irq(trigger=machine.Pin.IRQ_FALLING,
                handler=boot_pressed_handler)

while True:
    pass

MicroPython bluetooth (BLE) exampls, run on ESP32-C3.

This video just show how MicroPython bluetooth module examples run on ESP32-C3, Ai-Thinker NodeMCU ESP-C3-32S-Kit and Espressif ESP32-C3-DevKitM-1, both running MicroPython v1.19.1 on 2022-06-18. Finally, have bi-direction BLE communication between ESP32-C3 dev. boards.

---

MicroPython bluetooth module provides an interface to a Bluetooth controller on a board. Currently this supports Bluetooth Low Energy (BLE) in Central, Peripheral, Broadcaster, and Observer roles, as well as GATT Server and Client and L2CAP connection-oriented-channels. A device may operate in multiple roles concurrently. Pairing (and bonding) is supported on some ports.

Note: This module is still under development and its classes, functions, methods and constants are subject to change.

---

NEXT:
~ It's modified to send/receive command via BLE UART to control LED remotely.
~ ESP32-C3/MicroPython BLE UART Communication, with user input and display on SSD1306 I2C OLED.

MicroPython/NodeMCU ESP-C3-32S-Kit to control onboard LEDs

With MicroPython v1.19 firmware installed on Ai-Thinker NodeMCU ESP-C3-32S-Kit, this exercise control the onboard LEDs.

Refer to ESP-C3-32S-Kit Specification, there are Cool, Warm and a three-in-one RGB lamp on board.
- IO3  : RGB red lamp beads
- IO4  : RGB green lamp beads
- IO5  : RGB blue lamp beads
- IO18 : Warm color lamp beads
- IO19 : Cool color lamp beads
  (high level is valid)

Exercise code:

mpy_NodeMCU_ESP-C3-32S-Kit_RGB.py, control onboard LEDs as Digital Output.

"""
MicroPython/NodeMCU ESP-C3-32S-Kit exercise
to control RGB LED.
"""
import uos
import usys
from machine import Pin
import time

# NodeMCU ESP-C3-32S-Kit onboard LEDs assignment
pinR = Pin(3, Pin.OUT)
pinG = Pin(4, Pin.OUT)
pinB = Pin(5, Pin.OUT)
pinWarm = Pin(18, Pin.OUT)
pinCool = Pin(19, Pin.OUT)


print()

print("====================================")
print(usys.implementation[0], uos.uname()[3],
      "\nrun on", uos.uname()[4])
print("====================================")

while True:
    
    #All OFF
    pinR.value(0)
    pinG.value(0)
    pinB.value(0)
    pinWarm.value(0)
    pinCool.value(0)
    time.sleep(1)
    
    #turn ON WARM
    pinWarm.value(1)
    time.sleep(1)
    
    #turn ON COOL
    pinWarm.value(0)
    pinCool.value(1)
    time.sleep(1)
    
    #turn ON RED
    pinCool.value(0)
    pinR.value(1)
    time.sleep(1)
    
    #turn ON GREEN
    pinR.value(0)
    pinG.value(1)
    time.sleep(1)
    
    #turn ON BLUE
    pinG.value(0)
    pinB.value(1)
    time.sleep(1)
    
    #turn ON RED/GREEN/BLUE
    pinR.value(1)
    pinG.value(1)
    pinB.value(1)
    time.sleep(1)

mpy_NodeMCU_ESP-C3-32S-Kit_RGB_PWM.py, control onboard LEDs as PWM.

"""
MicroPython/NodeMCU ESP-C3-32S-Kit exercise
to control RGB LED (PWM).

# ref:
# https://docs.micropython.org/en/latest/esp32/quickref.html#pwm-pulse-width-modulation
"""
import uos
import usys
import time
from machine import Pin, PWM

print()

print("====================================")
print(usys.implementation[0], uos.uname()[3],
      "\nrun on", uos.uname()[4])
print("====================================")
time.sleep(1)

# NodeMCU ESP-C3-32S-Kit onboard LEDs assignment
pwmR = PWM(Pin(3))
pwmG = PWM(Pin(4))
pwmB = PWM(Pin(5))
pwmWarm = PWM(Pin(18))
pwmCool = PWM(Pin(19))

pwmR.freq(1000)    # set PWM frequency from 1Hz to 40MHz
pwmG.freq(1000)
pwmB.freq(1000)
pwmWarm.freq(1000)
pwmCool.freq(1000)

def PWMLedTest(pwmpin):
    for d in range(0, 1024):
        pwmpin.duty(d)
        time.sleep(0.005)
    for d in range(1023, -1, -1):
        pwmpin.duty(d)
        time.sleep(0.005)

while True:
    
    #All OFF
    pwmR.duty(0)
    pwmG.duty(0)
    pwmB.duty(0)
    pwmWarm.duty(0)
    pwmCool.duty(0)
    time.sleep(1)
    
    PWMLedTest(pwmR)
    time.sleep(0.5)
    PWMLedTest(pwmG)
    time.sleep(0.5)
    PWMLedTest(pwmB)
    time.sleep(0.5)
    PWMLedTest(pwmCool) 
    time.sleep(0.5)
    PWMLedTest(pwmWarm)

    time.sleep(1)

Updated@2022-08-15
It's found that Cool and Warm LEDs are mutual affected. It because Cool and Warm LEDs share a common current limit resistors. And also, R, G and B share common current limit resistors.

Check update post in my new blogspot coXXect > MicroPython/NodeMCU ESP-C3-32S-Kit control onboard LEDs

Flash MicroPython v1.19 firmware on ESP32-C3 (ESP32-C3-DevKitM-1/NodeMCU ESP-C3-32S-Kit)

To flash MicroPython v1.19 firmware on ESP32-C3, tested on Espressif ESP32-C3-DevKitM-1 and AI-Thinker NodeMCU ESP-C3-32S-Kit, both have a single USB connector. All steps run on Raspberry Pi.

To IDENTIFY connected USB port. 

- BEFORE Connect ESP32-C3 dev. board to USB
clear dmesg buffer:
$ sudo dmesg -c

- AFTER ESP32-C3 dev. board connected to USB
display dmesg:
$ dmesg

Download firmware.

Visit https://micropython.org/download/  to download for esp32c3.

Select "ESP32-C3 Espressif"

Flash Firmware.

To erase the entire flash using:

$ esptool.py --chip esp32c3 --port /dev/ttyUSB0 erase_flash

Flash firmware starting at address 0x0:

$ esptool.py --chip esp32c3 --port /dev/ttyUSB0 --baud 460800 write_flash -z 0x0 <.bin>

Finally, test with Thonny.

---

more exercise:
~ MicroPython/NodeMCU ESP-C3-32S-Kit to control onboard LEDs
~ MicroPython bluetooth (BLE) exampls
~ detect onboard BOOT button, and control onboard RGB LED (Neopixel)
~ send/receive command via BLE UART
~ multithreading exercise, get user input un-blocked using _thread
~ ESP32-C3/MicroPython + SSD1306 I2C OLED
~ ESP32-C3/MicroPython BLE UART Communication

ESP32-C3/MicroPython exercise: update time using ntptime

 MicroPython (v1.18 ) exercise run on ESP32-C3-DevKitM-1, to update time using utptime.

"""
MicroPython/ESP32C3 exercise run on ESP32-C3-DevKitM-1,
about time.
"""
import uos
import usys
import time

import network
import ntptime

TIME_OFFSET = +8 * 60 *60   #offset for your timezone

print("\n====================================")
print(usys.implementation[0], uos.uname()[3],
      "\nrun on", uos.uname()[4])
print("====================================\n")

def connect_and_update_ntptime():
    wlan = network.WLAN(network.STA_IF)
    wlan.active(True)
    wlan.disconnect()
    time.sleep(1)
    if not wlan.isconnected():
        print('connecting to network...')
        wlan.connect('ssid', 'password')
        while not wlan.isconnected():
            pass
    print('network config:', wlan.ifconfig())
    
    ntptime.settime()
    wlan.disconnect()

connect_and_update_ntptime()
now_localtime =time.localtime(time.time() + TIME_OFFSET)
print(now_localtime)

CircuitPython BLE UART between XIAO BLE Sense and ESP32-C3/S3

It's a exercise of CircuitPython to implement BLE UART between server and client. All boards are flashed with CircuitPython 7.2.4 firmware, with adafruit_ble 8.2.3.

The server side run on Seeed XIAO BLE Sense (nRF52840) + Expansion board. The code modified from Adafruit CircuitPython ble_uart_echo_test.py example, or here, setup BLE UART Server, but display on SSD1306 I2C OLED instead of echo back.

The client side run on Ai-Thinker NodeMCU ESP-C3-32S-Kit and Espressif ESP32-S3-DevKitC-1. The code modified from ble_uart_echo_client.py, or here. The user enter text in REPL to send to server side and display on SSD1306 I2C OLED.

un-solved issue:

If server side offline and the BLE link disconnected, then server side online again and re-connected, the client side will fail; tested on both ESP-C3-32S-Kit and ESP32-S3-DevKitC-1.

Exercise code:

cpyXIAOBLE_ble_uart_server_ssd1306.py, run on server side.

"""
Run CircuitPython 7.2.4 on
Seeed XIAO nRF52840 Sense with nRF52840 + Expansion Board.
Modified from ble_uart_echo_test.py.
Act as BLE server, wait connection and
display received line on ssd13106 OLED.

libs need:
- adafruit_ble folder
- adafruit_displayio_ssd1306.mpy
"""
import os
import sys
import board
import busio
import displayio
import adafruit_displayio_ssd1306

from adafruit_ble import BLERadio
from adafruit_ble.advertising.standard import ProvideServicesAdvertisement
from adafruit_ble.services.nordic import UARTService
from adafruit_ble import __name__ as BLE_NAME
from adafruit_ble import __version__ as BLE_VERSION

displayio.release_displays()

# Create the I2C interface and display object of SSD1306_I2C.
i2c = busio.I2C(board.SCL, board.SDA)

ssd1306_i2c_addr = 60
display_width =128
display_height = 64
display_bus = displayio.I2CDisplay(
    i2c, device_address=ssd1306_i2c_addr)
display = adafruit_displayio_ssd1306.SSD1306(
    display_bus, width=display_width, height=display_height)

# with displayio initialized, and have nothing displayed.
# displayio act like a REPL terminal.
# anything print() will be displayed on displayio also.

print("=================================================")
info = sys.implementation[0] + ' ' + os.uname()[3] + '\n' + \
       'run on ' + os.uname()[4]
print(info)
print("=================================================")
print(BLE_NAME, ":", BLE_VERSION)
print("=================================================")
print(adafruit_displayio_ssd1306.__name__, adafruit_displayio_ssd1306.__version__)
print("SCL: ", board.SCL)
print("SDA: ", board.SDA)

print(display)
print("display.width x height: ",
      display.width, " x ", display.height)
#=================================

ble = BLERadio()
uart = UARTService()
advertisement = ProvideServicesAdvertisement(uart)

#=== scroll up to print screen ===
print()
print()
print()
print(" ---- hello ----")

while True:
    ble.start_advertising(advertisement)
    print("Waiting to connect")
    while not ble.connected:
        pass
    print("Connected")
    while ble.connected:
        s = uart.readline()
        if s:
            print(s.decode())
            uart.write(s)

print("~ bye ~")

cpyESP32x3_ble_uart_client_repl.py, run on client side.

"""
Run CircuitPython 7.2.4 on
AITHinker ESP32-C3S_Kit with ESP32-C3FN4/ESP32-S3-DevKitC-1-N8R8 with ESP32S3.
Modified from ble_uart_echo_client.py.
Act as BLE client, connect to server,
get user input from REPL and send to server.

libs need:
- adafruit_ble folder
"""
import os
import sys
import time

from adafruit_ble import BLERadio
from adafruit_ble.advertising.standard import ProvideServicesAdvertisement
from adafruit_ble.services.nordic import UARTService
from adafruit_ble import __name__ as BLE_NAME
from adafruit_ble import __version__ as BLE_VERSION

print("=================================================")
info = sys.implementation[0] + ' ' + os.uname()[3] + '\n' + \
       'run on ' + os.uname()[4]
print(info)
print("=================================================")
print(BLE_NAME, ":", BLE_VERSION)
print("=================================================")

ble = BLERadio()
while True:
    while ble.connected and any(
        UARTService in connection for connection in ble.connections
    ):
        for connection in ble.connections:
            if UARTService not in connection:
                continue
            
            uart = connection[UARTService]
            
            # input() will block the code.
            # if connection lost while waiting user input,
            # ConnectionError will thrown in uart.write()
            userinput = input("\nEnter something: ")
            print(userinput)
            
            try:
                uart.write(userinput)
            except ConnectionError as exc:
                print("ConnectionError:", exc)
            
    print("disconnected, scanning")
    for advertisement in ble.start_scan(ProvideServicesAdvertisement, timeout=1):
        if UARTService not in advertisement.services:
            continue
        ble.connect(advertisement)
        print("connected")
        break
    ble.stop_scan()

---

It you cannot open two Thonny instance, read last post How to open dual Thonny instance.

First power-up NodeMCU ESP-C3-32S-Kit (pre-loaded with AT Command firmware)

First NodeMCU ESP-C3-32S-Kit I received pre-loaded with AT Command firmware.

Ai-Thinker NodeMCU ESP-C3-32S-Kit and ESP-S3-12K-Kit

Ai-Thinker NodeMCU:
ESP-C3-32S-Kit (internal 4M)
ESP-S3-12K-Kit

---

Check chip_id and flash_id using esptool:

$ esptool.py --chip auto --port /dev/ttyUSB0 chip_id
$ esptool.py --chip auto --port /dev/ttyUSB0 flash_id

for ESP-C3-32S-Kit:

pi@raspberrypi:~ $ esptool.py --chip auto --port /dev/ttyUSB0 chip_id
esptool.py v3.1
Serial port /dev/ttyUSB0
Connecting....
Detecting chip type... ESP32-C3
Chip is unknown ESP32-C3 (revision 3)
Features: Wi-Fi
Crystal is 40MHz
MAC: 34:b4:72:4e:19:f4
Uploading stub...
Running stub...
Stub running...
Warning: ESP32-C3 has no Chip ID. Reading MAC instead.
MAC: 34:b4:72:4e:19:f4
Hard resetting via RTS pin...
pi@raspberrypi:~ $ esptool.py --chip auto --port /dev/ttyUSB0 flash_id
esptool.py v3.1
Serial port /dev/ttyUSB0
Connecting....
Detecting chip type... ESP32-C3
Chip is unknown ESP32-C3 (revision 3)
Features: Wi-Fi
Crystal is 40MHz
MAC: 34:b4:72:4e:19:f4
Uploading stub...
Running stub...
Stub running...
Manufacturer: 20
Device: 4016
Detected flash size: 4MB
Hard resetting via RTS pin...

ESP-S3-12K-Kit:
(esptool v3.2 is needed, error reported in esptool v3.1)

Using esptool v3.1 on Raspberry Pi, detected as ESP32-S3(beta3) and reported "A fatal error occurred: Invalid head of packet (0x65)"!

pi@raspberrypi:~ $ esptool.py --chip auto --port /dev/ttyUSB0 chip_id
esptool.py v3.1
Serial port /dev/ttyUSB0
Connecting....
Detecting chip type... ESP32-S3(beta3)
Chip is ESP32-S3(beta3)
Features: WiFi, BLE
Crystal is 40MHz
MAC: 00:00:00:00:00:00
Uploading stub...
Running stub...
Stub running...
Warning: ESP32-S3(beta3) has no Chip ID. Reading MAC instead.

A fatal error occurred: Invalid head of packet (0x65)
pi@raspberrypi:~ $ esptool.py --chip auto --port /dev/ttyUSB0 flash_id
esptool.py v3.1
Serial port /dev/ttyUSB0
Connecting....
Detecting chip type... ESP32-S3(beta3)
Chip is ESP32-S3(beta3)
Features: WiFi, BLE
Crystal is 40MHz
MAC: 00:00:00:00:00:00
Uploading stub...
Running stub...
Stub running...

A fatal error occurred: Invalid head of packet (0x65)

Using esptool v3.2 on Linux Mint, detected as ESP32-S3 and no error.

eric@eric-VirtualBox:~$ esptool.py --chip auto --port /dev/ttyUSB0 chip_id
esptool.py v3.2
Serial port /dev/ttyUSB0
Connecting....
Detecting chip type... ESP32-S3
Chip is ESP32-S3
Features: WiFi, BLE
Crystal is 40MHz
MAC: f4:12:fa:43:65:2c
Uploading stub...
Running stub...
Stub running...
Warning: ESP32-S3 has no Chip ID. Reading MAC instead.
MAC: f4:12:fa:43:65:2c
Hard resetting via RTS pin...
eric@eric-VirtualBox:~$ esptool.py --chip auto --port /dev/ttyUSB0 flash_id
esptool.py v3.2
Serial port /dev/ttyUSB0
Connecting....
Detecting chip type... ESP32-S3
Chip is ESP32-S3
Features: WiFi, BLE
Crystal is 40MHz
MAC: f4:12:fa:43:65:2c
Uploading stub...
Running stub...
Stub running...
Manufacturer: c8
Device: 4017
Detected flash size: 8MB
Hard resetting via RTS pin...

to upgrade esptool, read Upgrade esptool using pip3.

Usefule links:
for ESP-C3-32S-Kit

~ ESP-C3-32S-Kit Specification

for ESP-S3-12K-Kit
~ ESP32-S3 series module
~ ESP-S3-12K-Kit specification (English)

~ ESP-S3-12K-Kit Schematic

Related:
~ First power-up NodeMCU ESP-C3-32S-Kit (pre-loaded with AT Command firmware)
~ Install CircuitPython 7.2.0 on ESP32-C3 (ESP32-C3-DevKitM-1/NodeMCU ESP-C3-32S-Kit)

~ arduino-esp32 2.0.3 now support ESP32-S3, try run on ESP-S3-12K-Kit
~ Flash MicroPython v1.19 firmware on ESP32-C3 (ESP32-C3-DevKitM-1/NodeMCU ESP-C3-32S-Kit)

ESP32-C3/CircuitPython 7.2.0 + ST7735 TFT, display bmp in slideshow, and using displayio.OnDiskBitmap/adafruit_imageload.

Exercise of using CircuitPython 7.2.0 on  ESP32-C3-DevKitM-1 with 1.44" 128x128 ST7735 SPI TFT (KMR1441_SPI V2):
- display bmp in slideshow
- display bmp using OnDiskBitmap/adafruit_imageload

The display module used in this exercise is a with 1.44" 128x128 SPI TFT marked "KMR1441_SPI V2".

Connection:

Firstly, connect the display to ESP32-C3-DevKitM-1.

	ST7735		ESP32-C3-DevKitM-1
	------------------------------
	VCC		3V3
	GND		GND
	CS		IO10
	RESET		IO1
	A0		IO0
	SDA		IO3
	SCK		IO2
	LED		3V3

Library:

Visit CircuitPython Library page to download Bundle for Version 7.x, and extract it.

Copy the libraries to lib folder in Circuit device.
- adafruit_st7735r.mpy
- adafruit_display_text folder
- adafruit_slideshow.mpy
- adafruit_imageload folder

Exercise code:

cpyESP32C3_st7735_128x128.py, functional testing.

"""
CircuitPython 7.2.0 exercise run on  ESP32-C3-DevKitM-1
with 1.44" 128x128 (KMR1441_SPI V2)

ref:
adafruit/Adafruit_CircuitPython_ST7735R
https://github.com/adafruit/Adafruit_CircuitPython_ST7735R
"""

from sys import implementation as sysImplementation
import time
import os
import board
import busio
import displayio
import terminalio

from adafruit_st7735r import ST7735R as TFT_ST7735
from adafruit_st7735r import __name__ as ST7735_NAME
from adafruit_st7735r import __version__ as ST7735_VERSION

from adafruit_display_text import label

# Release any resources currently in use for the displays
displayio.release_displays()

#Connection between ESP32-C3 and SPI ST7735 display
                        #marking on display
tft_sck = board.IO2     #SCK
tft_mosi = board.IO3    #SDA
tft_dc = board.IO0      #A0
tft_reset = board.IO1   #RESET
tft_cs = board.IO10     #CS
#Backlight (LED) connect to ESP32-C3 3V3
#TFT VCC - ESP32-C3 3V3
#TFT GND - ESP32-C3 GND

tft_spi = busio.SPI(clock=tft_sck, MOSI=tft_mosi)
display_bus = displayio.FourWire(
    tft_spi, command=tft_dc, chip_select=tft_cs, reset=tft_reset)

display = TFT_ST7735(display_bus, width=128, height=128,
                     rotation=90,
                     bgr=True)

strSys = sysImplementation[0] + ' ' + \
         str(sysImplementation[1][0]) +'.'+ \
         str(sysImplementation[1][1]) +'.'+ \
         str(sysImplementation[1][2])

print("==========================================")

print(strSys)
print('run on ' + os.uname()[4])
print('using', ST7735_NAME, ST7735_VERSION)
print("==========================================")

print(type(display))
print("display.width:  ", display.width)
print("display.height: ", display.height)

# Make the display context
splash = displayio.Group()
display.show(splash)

color_bitmap = displayio.Bitmap(display.width, display.height, 1)
color_palette = displayio.Palette(1)
color_palette[0] = 0x000000
time.sleep(1)

bg_sprite = displayio.TileGrid(color_bitmap,
                               pixel_shader=color_palette, x=0, y=0)
splash.append(bg_sprite)

for c in [["RED", 0xFF0000],
          ["GREEN", 0x00FF00],
          ["BLUE", 0x0000FF]]:
    print(c[0], " : ", hex(c[1]))
    color_palette[0] = c[1]
    time.sleep(2)

splash.remove(bg_sprite)
#---

# Make the display context
#splash = displayio.Group()
#display.show(splash)

color_bitmap = displayio.Bitmap(display.width, display.height, 1)
color_palette = displayio.Palette(1)
color_palette[0] = 0x00FF00

bg_sprite = displayio.TileGrid(color_bitmap,
                               pixel_shader=color_palette, x=0, y=0)
splash.append(bg_sprite)

# Draw a smaller inner rectangle
inner_bitmap = displayio.Bitmap(display.width-2, display.height-2, 1)
inner_palette = displayio.Palette(1)
inner_palette[0] = 0x0000FF
inner_sprite = displayio.TileGrid(inner_bitmap,
                                  pixel_shader=inner_palette, x=1, y=1)
splash.append(inner_sprite)

# Draw a label
text_group1 = displayio.Group(scale=1, x=5, y=10)
text1 = "ESP32-C3"
text_area1 = label.Label(terminalio.FONT, text=text1, color=0xFF0000)
text_group1.append(text_area1)  # Subgroup for text scaling

# Draw a label

text_group2 = displayio.Group(scale=1, x=5, y=25)
text2 = strSys
text_area2 = label.Label(terminalio.FONT, text=text2, color=0xFFFFFF)
text_group2.append(text_area2)  # Subgroup for text scaling

# Draw a label
text_group3 = displayio.Group(scale=1, x=5, y=40)
text3 = ST7735_NAME
text_area3 = label.Label(terminalio.FONT, text=text3, color=0x0000000)
text_group3.append(text_area3)  # Subgroup for text scaling
# Draw a label
text_group4 = displayio.Group(scale=1, x=5, y=55)
text4 = ST7735_VERSION
text_area4 = label.Label(terminalio.FONT, text=text4, color=0x000000)
text_group4.append(text_area4)  # Subgroup for text scaling

text_group5 = displayio.Group(scale=1, x=5, y=70)
text5 = str(display.width) + " x " + str(display.height)
text_area5 = label.Label(terminalio.FONT, text=text5, color=0x000000)
text_group5.append(text_area5)  # Subgroup for text scaling

splash.append(text_group1)
splash.append(text_group2)
splash.append(text_group3)
splash.append(text_group4)
splash.append(text_group5)

time.sleep(3.0)

rot = 90
while True:
    time.sleep(5.0)
    rot = rot + 90
    if (rot>=360):
        rot = 0
    display.rotation = rot

cpyESP32C3_st7735_slideshow.py, Test with exercise in "Creating Slideshows in CircuitPython".

"""
CircuitPython 7.2.0 exercise run on  ESP32-C3-DevKitM-1
with 1.44" 128x128 (KMR1441_SPI V2)
- slideshow

ref:
adafruit/Adafruit_CircuitPython_ST7735R
https://github.com/adafruit/Adafruit_CircuitPython_ST7735R
"""

from sys import implementation as sysImplementation
import time
import os
import board
import busio
import displayio
import terminalio

from adafruit_st7735r import ST7735R as TFT_ST7735
from adafruit_st7735r import __name__ as ST7735_NAME
from adafruit_st7735r import __version__ as ST7735_VERSION

from adafruit_display_text import label

# Release any resources currently in use for the displays
displayio.release_displays()

#Connection between ESP32-C3 and SPI ST7735 display
                        #marking on display
tft_sck = board.IO2     #SCK
tft_mosi = board.IO3    #SDA
tft_dc = board.IO0      #A0
tft_reset = board.IO1   #RESET
tft_cs = board.IO10     #CS
#Backlight (LED) connect to ESP32-C3 3V3
#TFT VCC - ESP32-C3 3V3
#TFT GND - ESP32-C3 GND

tft_spi = busio.SPI(clock=tft_sck, MOSI=tft_mosi)
display_bus = displayio.FourWire(
    tft_spi, command=tft_dc, chip_select=tft_cs, reset=tft_reset)

display = TFT_ST7735(display_bus, width=128, height=128,
                     rotation=90,
                     bgr=True)

strSys = sysImplementation[0] + ' ' + \
         str(sysImplementation[1][0]) +'.'+ \
         str(sysImplementation[1][1]) +'.'+ \
         str(sysImplementation[1][2])

print("==========================================")

print(strSys)
print('run on ' + os.uname()[4])
print('using', ST7735_NAME, ST7735_VERSION)
print("==========================================")

print(type(display))
print("display.width:  ", display.width)
print("display.height: ", display.height)

#===============================
# SPDX-FileCopyrightText: 2019 Anne Barela for Adafruit Industries
#
# SPDX-License-Identifier: MIT

# CircuitPython Slideshow - uses the adafruit_slideshow.mpy library
#import board
from adafruit_slideshow import PlayBackOrder, SlideShow

# Create the slideshow object that plays through once alphabetically.
slideshow = SlideShow(display,
                      folder="/images",
                      loop=True,
                      order=PlayBackOrder.ALPHABETICAL,
                      dwell=5)

while slideshow.update():
    pass

cpyESP32C3_st7735_OnDiskBitmap.py, test with OnDiskBitmap example in "Display a Bitmap".

"""
CircuitPython 7.2.0 exercise run on  ESP32-C3-DevKitM-1
with 1.44" 128x128 (KMR1441_SPI V2)
- OnDiskBitmap

ref:
adafruit/Adafruit_CircuitPython_ST7735R
https://github.com/adafruit/Adafruit_CircuitPython_ST7735R
"""

from sys import implementation as sysImplementation
import time
import os
import board
import busio
import displayio
import terminalio

from adafruit_st7735r import ST7735R as TFT_ST7735
from adafruit_st7735r import __name__ as ST7735_NAME
from adafruit_st7735r import __version__ as ST7735_VERSION

from adafruit_display_text import label

# Release any resources currently in use for the displays
displayio.release_displays()

#Connection between ESP32-C3 and SPI ST7735 display
                        #marking on display
tft_sck = board.IO2     #SCK
tft_mosi = board.IO3    #SDA
tft_dc = board.IO0      #A0
tft_reset = board.IO1   #RESET
tft_cs = board.IO10     #CS
#Backlight (LED) connect to ESP32-C3 3V3
#TFT VCC - ESP32-C3 3V3
#TFT GND - ESP32-C3 GND

tft_spi = busio.SPI(clock=tft_sck, MOSI=tft_mosi)
display_bus = displayio.FourWire(
    tft_spi, command=tft_dc, chip_select=tft_cs, reset=tft_reset)

display = TFT_ST7735(display_bus, width=128, height=128,
                     rotation=90,
                     bgr=True)

strSys = sysImplementation[0] + ' ' + \
         str(sysImplementation[1][0]) +'.'+ \
         str(sysImplementation[1][1]) +'.'+ \
         str(sysImplementation[1][2])

print("==========================================")

print(strSys)
print('run on ' + os.uname()[4])
print('using', ST7735_NAME, ST7735_VERSION)
print("==========================================")

print(type(display))
print("display.width:  ", display.width)
print("display.height: ", display.height)

#===============================
# SPDX-FileCopyrightText: 2019 Carter Nelson for Adafruit Industries
#
# SPDX-License-Identifier: MIT

#import board
#import displayio

#display = board.DISPLAY

# Future method for CircuitPython 7 onwards

# Setup the file as the bitmap data source
bitmap = displayio.OnDiskBitmap("images/002.bmp")

# Create a TileGrid to hold the bitmap
tile_grid = displayio.TileGrid(bitmap, pixel_shader=bitmap.pixel_shader)

# Create a Group to hold the TileGrid
group = displayio.Group()

# Add the TileGrid to the Group
group.append(tile_grid)

# Add the Group to the Display
display.show(group)

# Loop forever so you can enjoy your image
while True:
    pass

cpyESP32C3_st7735_ImageLoad.py, test with example of ImageLoad in "Display a Bitmap"

"""
CircuitPython 7.2.0 exercise run on  ESP32-C3-DevKitM-1
with 1.44" 128x128 (KMR1441_SPI V2)
- ImageLoad

ref:
adafruit/Adafruit_CircuitPython_ST7735R
https://github.com/adafruit/Adafruit_CircuitPython_ST7735R
"""

from sys import implementation as sysImplementation
import time
import os
import board
import busio
import displayio
import terminalio

from adafruit_st7735r import ST7735R as TFT_ST7735
from adafruit_st7735r import __name__ as ST7735_NAME
from adafruit_st7735r import __version__ as ST7735_VERSION

from adafruit_display_text import label

# Release any resources currently in use for the displays
displayio.release_displays()

#Connection between ESP32-C3 and SPI ST7735 display
                        #marking on display
tft_sck = board.IO2     #SCK
tft_mosi = board.IO3    #SDA
tft_dc = board.IO0      #A0
tft_reset = board.IO1   #RESET
tft_cs = board.IO10     #CS
#Backlight (LED) connect to ESP32-C3 3V3
#TFT VCC - ESP32-C3 3V3
#TFT GND - ESP32-C3 GND

tft_spi = busio.SPI(clock=tft_sck, MOSI=tft_mosi)
display_bus = displayio.FourWire(
    tft_spi, command=tft_dc, chip_select=tft_cs, reset=tft_reset)

display = TFT_ST7735(display_bus, width=128, height=128,
                     rotation=90,
                     bgr=True)

strSys = sysImplementation[0] + ' ' + \
         str(sysImplementation[1][0]) +'.'+ \
         str(sysImplementation[1][1]) +'.'+ \
         str(sysImplementation[1][2])

print("==========================================")

print(strSys)
print('run on ' + os.uname()[4])
print('using', ST7735_NAME, ST7735_VERSION)
print("==========================================")

print(type(display))
print("display.width:  ", display.width)
print("display.height: ", display.height)

#===============================
# SPDX-FileCopyrightText: 2019 Carter Nelson for Adafruit Industries
#
# SPDX-License-Identifier: MIT

#import board
#import displayio
import adafruit_imageload

#display = board.DISPLAY

bitmap, palette = adafruit_imageload.load("images/003i.bmp",
                                          bitmap=displayio.Bitmap,
                                          palette=displayio.Palette)

# Create a TileGrid to hold the bitmap
tile_grid = displayio.TileGrid(bitmap, pixel_shader=palette)

# Create a Group to hold the TileGrid
group = displayio.Group()

# Add the TileGrid to the Group
group.append(tile_grid)

# Add the Group to the Display
display.show(group)

# Loop forever so you can enjoy your image
while True:
    pass

Install CircuitPython 7.2.0 on ESP32-C3 (ESP32-C3-DevKitM-1/NodeMCU ESP-C3-32S-Kit)

CircuitPython 7.2.0 was released. With espressif ESP32-S3 and ESP32-C3 supported (considered alpha and will have bugs and missing functionality).

This post show how to install CircuitPython 7.2.0 on ESP32-C3-DevKitM-1 (ESP32-C3-MINI-1), using Raspberry Pi 4B running Raspberry Pi OS 32-bit (buster). Then test with exercise to read system info, control onboard RGB (NEOPIXEL), and 0.96" 80x160 IPS.



Download Firmware:

Visit CircuitPython Download page, search C3.

I can't find exact board named "ESP32-C3-DevKitM-1", so I try "ESP32-C3-DevKitC-1-N4 by Espressif". DOWNLOAD .BIN NOW under CircuitPython 7.2.0, it's adafruit-circuitpython-espressif_esp32c3_devkitm_1_n4-en_US-7.2.0.bin.

Identify USB port:

Before connect the board to USB.
Run the command to clear dmesg buffer -
$ sudo dmesg -c

Connect the ESP32-C3-DevKitM-1 board to USB.
Run dmesg again, the connected port will be shown -
$ dmesg

Install CircuitPython firmware using esptool:

esptool is needed to flash firmware on ESP devices.
~ Install esptool on Raspberry Pi OS (32 bit)

With esptool installed, you can check the ESP chip ID and Flash using commands:
$ esptool.py --chip auto --port /dev/ttyUSB0 chip_id
$ esptool.py --chip auto --port /dev/ttyUSB0 flash_id

To erase the flash, enter:

$ esptool.py --port /dev/ttyUSB0 erase_flash

To flash the firmware, I follow the command in MicroPython document > Getting started with MicroPython on the ESP32 > Deploying the firmware.
replace:
- chip to esp32c3
- port
- address start from 0x0
- file name

$ esptool.py --chip esp32c3 --port /dev/ttyUSB0 write_flash \-z 0x0 \
adafruit-circuitpython-espressif_esp32c3_devkitm_1_n4-en_US-7.2.0.bin

Exercise code:

cpyESP32C3_info.py, get CircuitPython info

"""
CircuitPython 7.2.0 exercise run on ESP32-C3,
get system info.
"""
import board
import sys
import os
"""
ref:
The entire table of ANSI color codes working in C:
https://gist.github.com/RabaDabaDoba/145049536f815903c79944599c6f952a
"""
class color:
   RED = '\033[1;31;48m'
   BLUE = '\033[1;34;48m'
   BLACK = '\033[1;30;48m'
   END = '\033[1;37;0m'

print(board.board_id)
print(sys.implementation[0] + ' ' +
      str(sys.implementation[1][0]) +'.'+
      str(sys.implementation[1][1]) +'.'+
      str(sys.implementation[1][2]))
print("==========================================")
info = color.RED + \
       sys.implementation[0] + ' ' + \
       os.uname()[3] + color.END + '\n' + \
       'run on ' + color.BLUE + os.uname()[4] + color.END
print(info)
print("==========================================")

print()

cpyESP32C3_NEOPIXEL.py, control onboard RGB (Neopixel).

import time
import os
import microcontroller
import neopixel
import board

def cycleNeopixel(wait):
    for r in range(255):
        pixel[0] = (r, 0, 0)
        time.sleep(wait)
    for r in range(255, 0, -1):
        pixel[0] = (r, 0, 0)
        time.sleep(wait)
        
    for g in range(255):
        pixel[0] = (0, g, 0)
        time.sleep(wait)
    for g in range(255, 0, -1):
        pixel[0] = (0, g, 0)
        time.sleep(wait)
        
    for b in range(255):
        pixel[0] = (0, 0, b)
        time.sleep(wait)
    for b in range(255, 0, -1):
        pixel[0] = (0, 0, b)
        time.sleep(wait)
        
print("==============================")
print("Hello ESP32-C3/CircuitPython NeoPixel exercise")
#print(os.uname())
for u in os.uname():
    print(u)
print()
print("neopixel version: " + neopixel.__version__)
print()

# Create the NeoPixel object
pixel = neopixel.NeoPixel(board.NEOPIXEL,
                          1,
                          pixel_order=neopixel.RGB)
pixel[0] = (0, 0, 0)
time.sleep(2.0)

cycleNeopixel(0.01)

pixel[0] = (0, 0, 0)
time.sleep(2.0)

print("- bye -\n")

cpyESP32C3_st7735_80x160.py, test with 0.96" 80x160 IPS.

"""
CircuitPython 7.2.0 exercise run on ESP32-C3
with unknown brand 0.96 inch 80x160 SPI ST7735 IPS

ref:
adafruit/Adafruit_CircuitPython_ST7735R
https://github.com/adafruit/Adafruit_CircuitPython_ST7735R
"""

from sys import implementation as sysImplementation
import time
import board
import busio
import displayio
import terminalio

from adafruit_st7735r import ST7735R as TFT_ST7735
from adafruit_st7735r import __name__ as ST7735_NAME
from adafruit_st7735r import __version__ as ST7735_VERSION

from adafruit_display_text import label

# Release any resources currently in use for the displays
displayio.release_displays()

#Connection between ESP32-C3 and SPI ST7735 display
                        #marking on display
tft_sck = board.IO2     #SCL
tft_mosi = board.IO3    #SDA
tft_reset = board.IO0   #RES
tft_dc = board.IO1      #DC
tft_cs = board.IO10     #CS
#Backlight (BLK) connect to ESP32-C3 3V3
#TFT VCC - ESP32-C31 3V3
#TFT GND - ESP32-C3 GND

tft_spi = busio.SPI(clock=tft_sck, MOSI=tft_mosi)
display_bus = displayio.FourWire(
    tft_spi, command=tft_dc, chip_select=tft_cs, reset=tft_reset
)

# I find out colrstart/rowstart by try/error and retry
display = TFT_ST7735(display_bus, width=160, height=80,
                     colstart=26, rowstart=1,
                     rotation=90,
                     invert=True
                     )

print(type(display))
print("display.width:  ", display.width)
print("display.height: ", display.height)

# Make the display context
splash = displayio.Group()
display.show(splash)

color_bitmap = displayio.Bitmap(display.width, display.height, 1)
color_palette = displayio.Palette(1)
color_palette[0] = 0x000000
time.sleep(1)

bg_sprite = displayio.TileGrid(color_bitmap,
                               pixel_shader=color_palette, x=0, y=0)
splash.append(bg_sprite)

for c in [["RED", 0xFF0000],
          ["GREEN", 0x00FF00],
          ["BLUE", 0x0000FF]]:
    print(c[0], " : ", hex(c[1]))
    color_palette[0] = c[1]
    time.sleep(2)

splash.remove(bg_sprite)
#---

# Make the display context
#splash = displayio.Group()
#display.show(splash)

color_bitmap = displayio.Bitmap(display.width, display.height, 1)
color_palette = displayio.Palette(1)
color_palette[0] = 0x00FF00

bg_sprite = displayio.TileGrid(color_bitmap,
                               pixel_shader=color_palette, x=0, y=0)
splash.append(bg_sprite)

# Draw a smaller inner rectangle
inner_bitmap = displayio.Bitmap(display.width-2, display.height-2, 1)
inner_palette = displayio.Palette(1)
inner_palette[0] = 0x0000FF
inner_sprite = displayio.TileGrid(inner_bitmap,
                                  pixel_shader=inner_palette, x=1, y=1)
splash.append(inner_sprite)

# Draw a label
text_group1 = displayio.Group(scale=1, x=5, y=10)
text1 = "ESP32-C3"
text_area1 = label.Label(terminalio.FONT, text=text1, color=0xFF0000)
text_group1.append(text_area1)  # Subgroup for text scaling

# Draw a label
strSys = sysImplementation[0] + ' ' + \
         str(sysImplementation[1][0]) +'.'+ \
         str(sysImplementation[1][1]) +'.'+ \
         str(sysImplementation[1][2])
text_group2 = displayio.Group(scale=1, x=5, y=25)
text2 = strSys
text_area2 = label.Label(terminalio.FONT, text=text2, color=0xFFFFFF)
text_group2.append(text_area2)  # Subgroup for text scaling

# Draw a label
text_group3 = displayio.Group(scale=1, x=5, y=40)
text3 = ST7735_NAME
text_area3 = label.Label(terminalio.FONT, text=text3, color=0x0000000)
text_group3.append(text_area3)  # Subgroup for text scaling
# Draw a label
text_group4 = displayio.Group(scale=1, x=5, y=55)
text4 = ST7735_VERSION
text_area4 = label.Label(terminalio.FONT, text=text4, color=0x000000)
text_group4.append(text_area4)  # Subgroup for text scaling

text_group5 = displayio.Group(scale=1, x=5, y=70)
text5 = str(display.width) + " x " + str(display.height)
text_area5 = label.Label(terminalio.FONT, text=text5, color=0x000000)
text_group5.append(text_area5)  # Subgroup for text scaling

splash.append(text_group1)
splash.append(text_group2)
splash.append(text_group3)
splash.append(text_group4)
splash.append(text_group5)

time.sleep(3.0)

rot = 90
while True:
    time.sleep(5.0)
    rot = rot + 90
    if (rot>=360):
        rot = 0
    display.rotation = rot

---

For NodeMCU ESP-C3-32S-Kit:

Download firmware for "ESP-C3-32S by Ai-Thinker",  adafruit-circuitpython-ai_thinker_esp32-c3s-en_US-7.2.0.bin.

Replace the file name in flashing command:

$ esptool.py --chip esp32c3 --port /dev/ttyUSB0 write_flash \-z 0x0
adafruit-circuitpython-ai_thinker_esp32-c3s-en_US-7.2.0.bin

cpyESP32C3_info.py run on NodeMCU ESP-C3-32S-Kit:

check the board assignment:

---

next:
~ ESP32-C3/CircuitPython 7.2.0 + ST7735 TFT, display bmp in slideshow, and using displayio.OnDiskBitmap/adafruit_imageload.

~ CircuitPython BLE UART between XIAO BLE Sense and ESP32-C3/S3