forked from lauri/micropython-skeleton
Added preliminary files
This commit is contained in:
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975c8f02de
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19
Makefile
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19
Makefile
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# Makefile for the board
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NAME=esp32-20180222-v1.9.3-347-g6e675c1b.bin
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all: flash console
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flash:
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esptool.py -p /dev/ttyUSB0 -b 921600 erase_flash
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esptool.py -p /dev/ttyUSB0 -b 921600 write_flash --flash_mode dio 0x1000 bin/${NAME}
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sleep 5
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ampy -p /dev/ttyUSB0 put ssd1306.py
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console:
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echo "Ctrl-A + Ctrl-Q to close Picocom"
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picocom -b115200 /dev/ttyUSB0
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dep:
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sudo apt install python3-pip
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sudo pip3 install adafruit-ampy
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192
README.md
192
README.md
@ -1,3 +1,193 @@
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# micropython-skeleton
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# Hello MicroPython
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## Getting started
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MicroPython project skeleton
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```
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git clone http://git.k-space.ee/lauri/micropython-skeleton
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cd micropython-skeleton
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make
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```
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First let's some LED-s blinking.
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Press Ctrl-E for paste mode, otherwise spaces get mangled.
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Press Ctrl-Shift-V for pasting.
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Press Ctrl-D to exit paste mode and evaluate the code.
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```
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from time import sleep
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from machine import Pin
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# RGB LED is connected to programmable pins 12, 13, 15
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led_red = Pin(12, Pin.OUT)
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led_green = Pin(13, Pin.OUT)
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led_blue = Pin(15, Pin.OUT)
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# The values are inverted because 3.3v is common pin
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led_red.value(1)
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led_green.value(1)
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led_blue.value(1)
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for j in range(0, 5):
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led_red.value(0)
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sleep(1)
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led_red.value(1)
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led_green.value(0)
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sleep(1)
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led_green.value(1)
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led_blue.value(0)
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sleep(1)
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led_blue.value(1)
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```
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Tasks:
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1. Modify the code so yellow, cyan, magenda and white would be included.
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# Button presses
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On the board there is button labelled "Boot", this is hooked up to pin 2.
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By default there is a resistor which pulls the voltage on the pin to 3.3v, but when button is pressed the pin is shorted to ground so the voltage goes to 0v.
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Most modern solutions use interrupts to detect voltage change on the pin:
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```
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from machine import Pin
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from time import sleep
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Pin(12, Pin.OUT).value(1)
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Pin(13, Pin.OUT).value(1)
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led_blue = Pin(15, Pin.OUT)
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button = Pin(0)
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turned_off = False
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def callback(p):
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global turned_off
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turned_off = not turned_off
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led_blue.value(turned_off)
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# Execute function 'callback' when voltage goes from 3.3v to 0v on pin 0
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button.irq(trigger=Pin.IRQ_FALLING, handler=callback)
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```
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Tasks:
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1. Modify the code so pressing button shuffles between off, red, green, blue, yellow, cyan, magenta and white
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# Driving OLED screens
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Let's get some pixels on the screen.
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There's 128x64 pixels monochrome OLED screen connected via I2C bus on the pins 4 and 5.
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```
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from machine import Pin, I2C
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from ssd1306 import SSD1306_I2C
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i2c = I2C(-1, Pin(4),Pin(5), freq=400000) # Bitbanged I2C bus
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oled = SSD1306_I2C(128, 64, i2c)
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oled.invert(0) # White text on black background
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oled.contrast(255) # Maximum contrast
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oled.fill(0)
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name = "Lauri"
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oled.text("Hi %s" % name, 10, 10)
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oled.show()
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```
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Tasks:
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1. When button is pressed show a corresponding message on the screen - lights turned on/off or the name of the color shown
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## Temperature & humidity
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Next let's hook up DHT11 sensor to the board and measure the temperature.
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```
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from time import sleep
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from machine import Pin
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from dht import DHT11
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d = DHT11(Pin(4))
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try:
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d.measure()
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except OSError:
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print("Sensor not connected")
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else:
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print("Temperature %sC" % d.temperature())
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print("Humidity %s%%" % d.humidity())
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finally:
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sleep(1)
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```
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Tasks:
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1. Get temperature and humidity displayed on the screen
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## Connecting to internet
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Exit the serial console by pressing Ctrl-A and then Ctrl-Q.
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Upload module to handle WebSockets and return to Python prompt:
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```
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ampy -p /dev/ttyUSB0 put uwebsockets.py
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ampy -p /dev/ttyUSB0 put boot.py # Script that connects to itcollege network
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make console
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```
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Press EN button on the board to reset the board.
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Paste following:
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```
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import sys
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import uwebsockets
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from machine import Pin
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Pin(12, Pin.OUT).value(1)
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Pin(13, Pin.OUT).value(1)
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led_blue = Pin(15, Pin.OUT)
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channel = "living-room-of-lauri"
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uri = "ws://iot.koodur.com:80/ws/" + channel
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print("Connecting to:", uri)
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conn = uwebsockets.connect(uri)
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conn.send("alive")
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turned_off = False
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while True:
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print("Reading message...")
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fin, opcode, data = conn.read_frame()
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if data == "toggle":
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turned_off = not turned_off
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led_blue.value(turned_off)
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else:
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print("Got unknown command:", data)
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```
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Using web browser navigate [here](http://iot.koodur.com/demo2.html#living-room-of-lauri)
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1. Move to another channel to prevent flipping lights in my living room
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2. Improve the code so the "Boot" button and button in the web interface both work simultaneously
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3. Download the HTML file and add buttons to select different colors, adjust Python code to handle new commands
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# Summary
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ESP32 microcontroller with MicroPython is a really cheap way to get started with the IoT stuff. See more detailed information [here](https://lauri.xn--vsandi-pxa.com/2017/06/espressif.html).
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Some more tricks to try:
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* Add dimming of LED-s with PWM
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* Add [colorpicker](https://developer.mozilla.org/en-US/docs/Web/HTML/Element/input/color)
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Other interesting projects with ESP8266 and ESP32 microcontrollers:
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* [Nixie clock](https://github.com/k-space-ee/nixiesp12) with ESP8266
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* [Sumorobot](http://robot.itcollege.ee/sumorobot/2017/08/25/sumesp-prototype/) with ESP32
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BIN
bin/esp32-20180222-v1.9.3-347-g6e675c1b.bin
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BIN
bin/esp32-20180222-v1.9.3-347-g6e675c1b.bin
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Binary file not shown.
5
boot.py
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5
boot.py
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# Connect to wireless network as client
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import network
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wlan = network.WLAN(network.STA_IF)
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wlan.active(True)
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wlan.connect("itcollege")
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18
main.py
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main.py
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from time import sleep_ms
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from machine import Pin, I2C
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from ssd1306 import SSD1306_I2C
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i2c = I2C(-1, Pin(4),Pin(5),freq=400000) # Bitbanged I2C bus
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assert 60 in i2c.scan(), "No OLED display detected!"
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oled = SSD1306_I2C(128, 64, i2c)
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buf = "wubba lubba dub dub "
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oled.invert(0) # White text on black background
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oled.contrast(255) # Maximum contrast
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j = 0
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while True:
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oled.fill(0)
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oled.text(buf[j%len(buf):]+buf, 10, 10)
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oled.show()
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sleep_ms(20)
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j += 1
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ssd1306.py
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ssd1306.py
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# MicroPython SSD1306 OLED driver, I2C and SPI interfaces
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from micropython import const
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import framebuf
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# register definitions
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SET_CONTRAST = const(0x81)
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SET_ENTIRE_ON = const(0xa4)
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SET_NORM_INV = const(0xa6)
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SET_DISP = const(0xae)
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SET_MEM_ADDR = const(0x20)
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SET_COL_ADDR = const(0x21)
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SET_PAGE_ADDR = const(0x22)
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SET_DISP_START_LINE = const(0x40)
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SET_SEG_REMAP = const(0xa0)
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SET_MUX_RATIO = const(0xa8)
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SET_COM_OUT_DIR = const(0xc0)
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SET_DISP_OFFSET = const(0xd3)
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SET_COM_PIN_CFG = const(0xda)
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SET_DISP_CLK_DIV = const(0xd5)
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SET_PRECHARGE = const(0xd9)
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SET_VCOM_DESEL = const(0xdb)
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SET_CHARGE_PUMP = const(0x8d)
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# Subclassing FrameBuffer provides support for graphics primitives
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# http://docs.micropython.org/en/latest/pyboard/library/framebuf.html
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class SSD1306(framebuf.FrameBuffer):
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def __init__(self, width, height, external_vcc):
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self.width = width
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self.height = height
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self.external_vcc = external_vcc
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self.pages = self.height // 8
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self.buffer = bytearray(self.pages * self.width)
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super().__init__(self.buffer, self.width, self.height, framebuf.MONO_VLSB)
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self.init_display()
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def init_display(self):
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for cmd in (
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SET_DISP | 0x00, # off
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# address setting
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SET_MEM_ADDR, 0x00, # horizontal
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# resolution and layout
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SET_DISP_START_LINE | 0x00,
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SET_SEG_REMAP | 0x01, # column addr 127 mapped to SEG0
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SET_MUX_RATIO, self.height - 1,
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SET_COM_OUT_DIR | 0x08, # scan from COM[N] to COM0
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SET_DISP_OFFSET, 0x00,
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SET_COM_PIN_CFG, 0x02 if self.height == 32 else 0x12,
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# timing and driving scheme
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SET_DISP_CLK_DIV, 0x80,
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SET_PRECHARGE, 0x22 if self.external_vcc else 0xf1,
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SET_VCOM_DESEL, 0x30, # 0.83*Vcc
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# display
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SET_CONTRAST, 0xff, # maximum
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SET_ENTIRE_ON, # output follows RAM contents
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SET_NORM_INV, # not inverted
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# charge pump
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SET_CHARGE_PUMP, 0x10 if self.external_vcc else 0x14,
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SET_DISP | 0x01): # on
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self.write_cmd(cmd)
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self.fill(0)
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self.show()
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def poweroff(self):
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self.write_cmd(SET_DISP | 0x00)
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def poweron(self):
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self.write_cmd(SET_DISP | 0x01)
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def contrast(self, contrast):
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self.write_cmd(SET_CONTRAST)
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self.write_cmd(contrast)
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def invert(self, invert):
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self.write_cmd(SET_NORM_INV | (invert & 1))
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def show(self):
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x0 = 0
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x1 = self.width - 1
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if self.width == 64:
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# displays with width of 64 pixels are shifted by 32
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x0 += 32
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x1 += 32
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self.write_cmd(SET_COL_ADDR)
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self.write_cmd(x0)
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self.write_cmd(x1)
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self.write_cmd(SET_PAGE_ADDR)
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self.write_cmd(0)
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self.write_cmd(self.pages - 1)
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self.write_data(self.buffer)
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class SSD1306_I2C(SSD1306):
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def __init__(self, width, height, i2c, addr=0x3c, external_vcc=False):
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self.i2c = i2c
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self.addr = addr
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self.temp = bytearray(2)
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super().__init__(width, height, external_vcc)
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def write_cmd(self, cmd):
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self.temp[0] = 0x80 # Co=1, D/C#=0
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self.temp[1] = cmd
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self.i2c.writeto(self.addr, self.temp)
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def write_data(self, buf):
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self.temp[0] = self.addr << 1
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self.temp[1] = 0x40 # Co=0, D/C#=1
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self.i2c.start()
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self.i2c.write(self.temp)
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self.i2c.write(buf)
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self.i2c.stop()
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class SSD1306_SPI(SSD1306):
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def __init__(self, width, height, spi, dc, res, cs, external_vcc=False):
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self.rate = 10 * 1024 * 1024
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dc.init(dc.OUT, value=0)
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res.init(res.OUT, value=0)
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cs.init(cs.OUT, value=1)
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self.spi = spi
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self.dc = dc
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self.res = res
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self.cs = cs
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import time
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self.res(1)
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time.sleep_ms(1)
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self.res(0)
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time.sleep_ms(10)
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self.res(1)
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super().__init__(width, height, external_vcc)
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def write_cmd(self, cmd):
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self.spi.init(baudrate=self.rate, polarity=0, phase=0)
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self.cs(1)
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self.dc(0)
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self.cs(0)
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self.spi.write(bytearray([cmd]))
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self.cs(1)
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def write_data(self, buf):
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self.spi.init(baudrate=self.rate, polarity=0, phase=0)
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self.cs(1)
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self.dc(1)
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self.cs(0)
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self.spi.write(buf)
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self.cs(1)
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235
uwebsockets.py
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235
uwebsockets.py
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"""
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Websockets client for micropython
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Based very heavily on
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https://github.com/aaugustin/websockets/blob/master/websockets/client.py
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"""
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import ubinascii as binascii
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import urandom as random
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import ure as re
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import ustruct as struct
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import usocket as socket
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from ucollections import namedtuple
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# Opcodes
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OP_CONT = const(0x0)
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OP_TEXT = const(0x1)
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OP_BYTES = const(0x2)
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OP_CLOSE = const(0x8)
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OP_PING = const(0x9)
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OP_PONG = const(0xa)
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# Close codes
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CLOSE_OK = const(1000)
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CLOSE_GOING_AWAY = const(1001)
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CLOSE_PROTOCOL_ERROR = const(1002)
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CLOSE_DATA_NOT_SUPPORTED = const(1003)
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CLOSE_BAD_DATA = const(1007)
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CLOSE_POLICY_VIOLATION = const(1008)
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CLOSE_TOO_BIG = const(1009)
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CLOSE_MISSING_EXTN = const(1010)
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CLOSE_BAD_CONDITION = const(1011)
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URL_RE = re.compile(r'ws://([A-Za-z0-9\-\.]+)(?:\:([0-9]+))?(/.+)?')
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URI = namedtuple('URI', ('hostname', 'port', 'path'))
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def urlparse(uri):
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match = URL_RE.match(uri)
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if match:
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return URI(match.group(1), int(match.group(2)), match.group(3))
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else:
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raise ValueError("Invalid URL: %s" % uri)
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class Websocket:
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is_client = False
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def __init__(self, sock):
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self._sock = sock
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self.open = True
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def __enter__(self):
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return self
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def __exit__(self, exc_type, exc, tb):
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self.close()
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def settimeout(self, timeout):
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self._sock.settimeout(timeout)
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def read_frame(self, max_size=None):
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# Frame header
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byte1, byte2 = struct.unpack('!BB', self._sock.read(2))
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# Byte 1: FIN(1) _(1) _(1) _(1) OPCODE(4)
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fin = bool(byte1 & 0x80)
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opcode = byte1 & 0x0f
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# Byte 2: MASK(1) LENGTH(7)
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mask = bool(byte2 & (1 << 7))
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length = byte2 & 0x7f
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if length == 126: # Magic number, length header is 2 bytes
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length, = struct.unpack('!H', self._sock.read(2))
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elif length == 127: # Magic number, length header is 8 bytes
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length, = struct.unpack('!Q', self._sock.read(8))
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||||
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if mask: # Mask is 4 bytes
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mask_bits = self._sock.read(4)
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try:
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data = self._sock.read(length)
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except MemoryError:
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# We can't receive this many bytes, close the socket
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self.close(code=CLOSE_TOO_BIG)
|
||||
return True, OP_CLOSE, None
|
||||
|
||||
if mask:
|
||||
data = bytes(b ^ mask_bits[i % 4]
|
||||
for i, b in enumerate(data))
|
||||
|
||||
return fin, opcode, data.decode("utf-8")
|
||||
|
||||
def write_frame(self, opcode, data=b''):
|
||||
|
||||
fin = True
|
||||
mask = self.is_client # messages sent by client are masked
|
||||
|
||||
length = len(data)
|
||||
|
||||
# Frame header
|
||||
# Byte 1: FIN(1) _(1) _(1) _(1) OPCODE(4)
|
||||
byte1 = 0x80 if fin else 0
|
||||
byte1 |= opcode
|
||||
|
||||
# Byte 2: MASK(1) LENGTH(7)
|
||||
byte2 = 0x80 if mask else 0
|
||||
|
||||
if length < 126: # 126 is magic value to use 2-byte length header
|
||||
byte2 |= length
|
||||
self._sock.write(struct.pack('!BB', byte1, byte2))
|
||||
|
||||
elif length < (1 << 16): # Length fits in 2-bytes
|
||||
byte2 |= 126 # Magic code
|
||||
self._sock.write(struct.pack('!BBH', byte1, byte2, length))
|
||||
|
||||
elif length < (1 << 64):
|
||||
byte2 |= 127 # Magic code
|
||||
self._sock.write(struct.pack('!BBQ', byte1, byte2, length))
|
||||
|
||||
else:
|
||||
raise ValueError()
|
||||
|
||||
if mask: # Mask is 4 bytes
|
||||
mask_bits = struct.pack('!I', random.getrandbits(32))
|
||||
self._sock.write(mask_bits)
|
||||
|
||||
data = bytes(b ^ mask_bits[i % 4]
|
||||
for i, b in enumerate(data))
|
||||
|
||||
self._sock.write(data)
|
||||
|
||||
def recv(self):
|
||||
assert self.open
|
||||
|
||||
while self.open:
|
||||
try:
|
||||
fin, opcode, data = self.read_frame()
|
||||
except ValueError:
|
||||
self._close()
|
||||
return
|
||||
|
||||
if not fin:
|
||||
raise NotImplementedError()
|
||||
|
||||
if opcode == OP_TEXT:
|
||||
return data.decode('utf-8')
|
||||
elif opcode == OP_BYTES:
|
||||
return data
|
||||
elif opcode == OP_CLOSE:
|
||||
self._close()
|
||||
return
|
||||
elif opcode == OP_PONG:
|
||||
# Ignore this frame, keep waiting for a data frame
|
||||
continue
|
||||
elif opcode == OP_PING:
|
||||
# We need to send a pong frame
|
||||
self.write_frame(OP_PONG, data)
|
||||
# And then wait to receive
|
||||
continue
|
||||
elif opcode == OP_CONT:
|
||||
# This is a continuation of a previous frame
|
||||
raise NotImplementedError(opcode)
|
||||
else:
|
||||
raise ValueError(opcode)
|
||||
|
||||
def send(self, buf):
|
||||
|
||||
assert self.open
|
||||
|
||||
if isinstance(buf, str):
|
||||
opcode = OP_TEXT
|
||||
buf = buf.encode('utf-8')
|
||||
elif isinstance(buf, bytes):
|
||||
opcode = OP_BYTES
|
||||
else:
|
||||
raise TypeError()
|
||||
|
||||
self.write_frame(opcode, buf)
|
||||
|
||||
def close(self, code=CLOSE_OK, reason=''):
|
||||
|
||||
if not self.open:
|
||||
return
|
||||
|
||||
buf = struct.pack('!H', code) + reason.encode('utf-8')
|
||||
|
||||
self.write_frame(OP_CLOSE, buf)
|
||||
self._close()
|
||||
|
||||
def _close(self):
|
||||
self.open = False
|
||||
self._sock.close()
|
||||
|
||||
class WebsocketClient(Websocket):
|
||||
is_client = True
|
||||
|
||||
|
||||
def connect(uri):
|
||||
"""
|
||||
Connect a websocket.
|
||||
"""
|
||||
|
||||
uri = urlparse(uri)
|
||||
assert uri
|
||||
|
||||
sock = socket.socket()
|
||||
addr = socket.getaddrinfo(uri.hostname, uri.port)
|
||||
sock.connect(addr[0][4])
|
||||
|
||||
def send_header(header, *args):
|
||||
sock.send(header % args + '\r\n')
|
||||
|
||||
# Sec-WebSocket-Key is 16 bytes of random base64 encoded
|
||||
key = binascii.b2a_base64(bytes(random.getrandbits(8)
|
||||
for _ in range(16)))[:-1]
|
||||
|
||||
send_header(b'GET %s HTTP/1.1', uri.path or '/')
|
||||
send_header(b'Host: %s:%s', uri.hostname, uri.port)
|
||||
send_header(b'Connection: Upgrade')
|
||||
send_header(b'Upgrade: websocket')
|
||||
send_header(b'Sec-WebSocket-Key: %s', key)
|
||||
send_header(b'Sec-WebSocket-Version: 13')
|
||||
send_header(b'Origin: http://localhost')
|
||||
send_header(b'')
|
||||
|
||||
header = sock.readline()[:-2]
|
||||
assert header == b'HTTP/1.1 101 Switching Protocols', header
|
||||
|
||||
# We don't (currently) need these headers
|
||||
# FIXME: should we check the return key?
|
||||
while header:
|
||||
header = sock.readline()[:-2]
|
||||
|
||||
return WebsocketClient(sock)
|
Loading…
Reference in New Issue
Block a user