grow-python/examples/combined.py

#!/usr/bin/env python3

import time
import colorsys
import sys
import ST7735


from grow import moisture
from grow import pump
from subprocess import PIPE, Popen
from PIL import Image
from PIL import ImageDraw
from PIL import ImageFont
from fonts.ttf import RobotoMedium as UserFont
import logging

logging.basicConfig(
    format='%(asctime)s.%(msecs)03d %(levelname)-8s %(message)s',
    level=logging.INFO,
    datefmt='%Y-%m-%d %H:%M:%S')

logging.info("""all-in-one.py - Displays readings from all of Enviro plus' sensors

Press Ctrl+C to exit!

""")

# Create ST7735 LCD display class
st7735 = ST7735.ST7735(
    port=0,
    cs=1,
    dc=9,
    backlight=12,
    rotation=270,
    spi_speed_hz=10000000
)

# Initialize display
st7735.begin()

WIDTH = st7735.width
HEIGHT = st7735.height

# Set up canvas and font
img = Image.new('RGB', (WIDTH, HEIGHT), color=(0, 0, 0))
draw = ImageDraw.Draw(img)
font_size_small = 10
font_size_large = 20
font = ImageFont.truetype(UserFont, font_size_large)
smallfont = ImageFont.truetype(UserFont, font_size_small)
x_offset = 2
y_offset = 2

message = ""

# The position of the top bar
top_pos = 25

# Create a values dict to store the data
variables = ["moisture1",
             "moisture2",
             "moisture3",
             "pump1",
             "pump2",
             "pump3"]

units = ["Hz",
         "Hz",
         "Hz",
         "",
         "",
         ""]

# Define your own warning limits
# The limits definition follows the order of the variables array
# Example limits explanation for temperature:
# [4,18,28,35] means
# [-273.15 .. 4] -> Dangerously Low
# (4 .. 18]      -> Low
# (18 .. 28]     -> Normal
# (28 .. 35]     -> High
# (35 .. MAX]    -> Dangerously High
# DISCLAIMER: The limits provided here are just examples and come
# with NO WARRANTY. The authors of this example code claim
# NO RESPONSIBILITY if reliance on the following values or this
# code in general leads to ANY DAMAGES or DEATH.
limits = [[4, 18, 28, 35],
          [250, 650, 1013.25, 1015],
          [20, 30, 60, 70],
          [-1, -1, 30000, 100000],
          [-1, -1, 40, 50],
          [-1, -1, 450, 550]]

# RGB palette for values on the combined screen
palette = [(0, 0, 255),           # Dry
           (0, 255, 255),         # Damp
           (0, 255, 0),           # Moist
           (255, 255, 0)]         # Wet

values = {}


# Displays data and text on the 0.96" LCD
def display_text(variable, data, unit):
    # Maintain length of list
    values[variable] = values[variable][1:] + [data]
    # Scale the values for the variable between 0 and 1
    vmin = min(values[variable])
    vmax = max(values[variable])
    colours = [(v - vmin + 1) / (vmax - vmin + 1) for v in values[variable]]
    # Format the variable name and value
    message = "{}: {:.1f} {}".format(variable[:4], data, unit)
    logging.info(message)
    draw.rectangle((0, 0, WIDTH, HEIGHT), (255, 255, 255))
    for i in range(len(colours)):
        # Convert the values to colours from red to blue
        colour = (1.0 - colours[i]) * 0.6
        r, g, b = [int(x * 255.0) for x in colorsys.hsv_to_rgb(colour, 1.0, 1.0)]
        # Draw a 1-pixel wide rectangle of colour
        draw.rectangle((i, top_pos, i + 1, HEIGHT), (r, g, b))
        # Draw a line graph in black
        line_y = HEIGHT - (top_pos + (colours[i] * (HEIGHT - top_pos))) + top_pos
        draw.rectangle((i, line_y, i + 1, line_y + 1), (0, 0, 0))
    # Write the text at the top in black
    draw.text((0, 0), message, font=font, fill=(0, 0, 0))
    st7735.display(img)


# Saves the data to be used in the graphs later and prints to the log
def save_data(idx, data):
    variable = variables[idx]
    # Maintain length of list
    values[variable] = values[variable][1:] + [data]
    unit = units[idx]
    message = "{}: {:.1f} {}".format(variable[:4], data, unit)
    logging.info(message)


# Displays all the text on the 0.96" LCD
def display_everything():
    draw.rectangle((0, 0, WIDTH, HEIGHT), (0, 0, 0))
    column_count = 2
    row_count = (len(variables) / column_count)
    for i in range(len(variables)):
        variable = variables[i]
        data_value = values[variable][-1]
        unit = units[i]
        x = x_offset + ((WIDTH / column_count) * (i / row_count))
        y = y_offset + ((HEIGHT / row_count) * (i % row_count))
        message = "{}: {:.1f} {}".format(variable[:4], data_value, unit)
        lim = limits[i]
        rgb = palette[0]
        for j in range(len(lim)):
            if data_value > lim[j]:
                rgb = palette[j + 1]
        draw.text((x, y), message, font=smallfont, fill=rgb)
    st7735.display(img)


# Get the temperature of the CPU for compensation
def get_cpu_temperature():
    process = Popen(['vcgencmd', 'measure_temp'], stdout=PIPE, universal_newlines=True)
    output, _error = process.communicate()
    return float(output[output.index('=') + 1:output.rindex("'")])


def main():
    # Tuning factor for compensation. Decrease this number to adjust the
    # temperature down, and increase to adjust up
    factor = 2.25

    cpu_temps = [get_cpu_temperature()] * 5

    delay = 0.5  # Debounce the proximity tap
    mode = 10    # The starting mode
    last_page = 0

    for v in variables:
        values[v] = [1] * WIDTH

    # The main loop
    try:
        while True:
            proximity = ltr559.get_proximity()

            # If the proximity crosses the threshold, toggle the mode
            if proximity > 1500 and time.time() - last_page > delay:
                mode += 1
                mode %= (len(variables) + 1)
                last_page = time.time()

            # One mode for each variable
            if mode == 0:
                # variable = "temperature"
                unit = "C"
                cpu_temp = get_cpu_temperature()
                # Smooth out with some averaging to decrease jitter
                cpu_temps = cpu_temps[1:] + [cpu_temp]
                avg_cpu_temp = sum(cpu_temps) / float(len(cpu_temps))
                raw_temp = bme280.get_temperature()
                data = raw_temp - ((avg_cpu_temp - raw_temp) / factor)
                display_text(variables[mode], data, unit)

            if mode == 1:
                # variable = "pressure"
                unit = "hPa"
                data = bme280.get_pressure()
                display_text(variables[mode], data, unit)

            if mode == 2:
                # variable = "humidity"
                unit = "%"
                data = bme280.get_humidity()
                display_text(variables[mode], data, unit)

            if mode == 3:
                # variable = "light"
                unit = "Lux"
                if proximity < 10:
                    data = ltr559.get_lux()
                else:
                    data = 1
                display_text(variables[mode], data, unit)

            if mode == 4:
                # variable = "oxidised"
                unit = "kO"
                data = gas.read_all()
                data = data.oxidising / 1000
                display_text(variables[mode], data, unit)

            if mode == 5:
                # variable = "reduced"
                unit = "kO"
                data = gas.read_all()
                data = data.reducing / 1000
                display_text(variables[mode], data, unit)

            if mode == 6:
                # variable = "nh3"
                unit = "kO"
                data = gas.read_all()
                data = data.nh3 / 1000
                display_text(variables[mode], data, unit)

            if mode == 7:
                # variable = "pm1"
                unit = "ug/m3"
                try:
                    data = pms5003.read()
                except pmsReadTimeoutError:
                    logging.warn("Failed to read PMS5003")
                else:
                    data = float(data.pm_ug_per_m3(1.0))
                    display_text(variables[mode], data, unit)

            if mode == 8:
                # variable = "pm25"
                unit = "ug/m3"
                try:
                    data = pms5003.read()
                except pmsReadTimeoutError:
                    logging.warn("Failed to read PMS5003")
                else:
                    data = float(data.pm_ug_per_m3(2.5))
                    display_text(variables[mode], data, unit)

            if mode == 9:
                # variable = "pm10"
                unit = "ug/m3"
                try:
                    data = pms5003.read()
                except pmsReadTimeoutError:
                    logging.warn("Failed to read PMS5003")
                else:
                    data = float(data.pm_ug_per_m3(10))
                    display_text(variables[mode], data, unit)
            if mode == 10:
                # Everything on one screen
                cpu_temp = get_cpu_temperature()
                # Smooth out with some averaging to decrease jitter
                cpu_temps = cpu_temps[1:] + [cpu_temp]
                avg_cpu_temp = sum(cpu_temps) / float(len(cpu_temps))
                raw_temp = bme280.get_temperature()
                raw_data = raw_temp - ((avg_cpu_temp - raw_temp) / factor)
                save_data(0, raw_data)
                display_everything()
                raw_data = bme280.get_pressure()
                save_data(1, raw_data)
                display_everything()
                raw_data = bme280.get_humidity()
                save_data(2, raw_data)
                if proximity < 10:
                    raw_data = ltr559.get_lux()
                else:
                    raw_data = 1
                save_data(3, raw_data)
                display_everything()
                gas_data = gas.read_all()
                save_data(4, gas_data.oxidising / 1000)
                save_data(5, gas_data.reducing / 1000)
                save_data(6, gas_data.nh3 / 1000)
                display_everything()
                pms_data = None
                try:
                    pms_data = pms5003.read()
                except pmsReadTimeoutError:
                    logging.warn("Failed to read PMS5003")
                else:
                    save_data(7, float(pms_data.pm_ug_per_m3(1.0)))
                    save_data(8, float(pms_data.pm_ug_per_m3(2.5)))
                    save_data(9, float(pms_data.pm_ug_per_m3(10)))
                    display_everything()

    # Exit cleanly
    except KeyboardInterrupt:
        sys.exit(0)


if __name__ == "__main__":
    main()