main
Felix Pankratz 3 months ago
parent d15eddd2bc
commit 5c1d524ee0

@ -2,9 +2,10 @@
import cairo
import math
import datetime
from datetime import datetime
import calendar
import random
import colorsys
from utils import random_color
@ -25,53 +26,49 @@ DARK_BG = True
# precision of the calculation
PRECISION = 10000
def days_color(date):
import colorsys
def days_color(date: datetime) -> tuple[float, float, float]:
'''Return a color based on the progress through the year.'''
# a day between 1 and 365 (inclusive)
today = date.timetuple().tm_yday
year = date.year
days_in_year = 365 + calendar.isleap(year)
days_in_year = 365 + calendar.isleap(date.year)
# between 0 and 1, how far through the year are we?
progress = today/days_in_year
return colorsys.hsv_to_rgb(progress, 1, 0.9)
def days_amp(date, waves):
day = date.day
def days_amp(date: datetime, waves) -> float:
'''Return the amplitude of waves, based on progress through the month.'''
days_in_month = calendar.monthrange(date.year, date.month)[1]
max_amp = 1/waves/2
return day/days_in_month * max_amp
return date.day/days_in_month * max_amp
def days_count(date):
return date.month
def create_wpotd(output):
surface = cairo.ImageSurface(cairo.FORMAT_ARGB32, WIDTH, HEIGHT)
def create_wpotd(width: int, height: int):
#TODO: return a `file`-like object
surface = cairo.ImageSurface(cairo.FORMAT_ARGB32, width, height)
ctx = cairo.Context(surface)
ctx.scale(WIDTH, HEIGHT) # Normalizing the canvas
ctx.scale(width, height) # Normalizing the canvas
#ctx.set_antialias(cairo.Antialias.BEST)
step_size = 1/PRECISION
lastpoints = [(x/PRECISION, 0) for x in range(PRECISION+1)]
#date = datetime.datetime.strptime('2021-06-30', '%Y-%m-%d')
date = datetime.datetime.today()
date = datetime.today()
frequency = random.randint(10, 40)
if DATE_BASED_COUNT:
waves = days_count(date)
# generate as many waves as the number of the current month
waves = date.month
else:
waves = 12
if DATE_BASED_AMPLITUDE:
amplitude = days_amp(date, waves)
else:
amplitude = 25
if MONOCHROME:
if DATE_BASED_COLOR:
r, g, b = days_color(date) #datetime.datetime.now())
else:
r, g, b = random_color()
alpha_step = 1/waves
if DARK_BG:
# make bg black
ctx.rectangle(0, 0, 1, 1)
@ -79,20 +76,24 @@ def create_wpotd(output):
ctx.fill()
wave_height = 1/waves
for num in range(waves+1):
step_size = 1/PRECISION
for wave_index in range(waves+1):
if not MONOCHROME:
r, g, b = random_color()
points = []
x = 0
while x < 1:
y = amplitude * math.sin(frequency * x + (num * WAVE_OFFSET) )
points.append((x, ( y + (0.5+num)*wave_height)))
# step along, create points along the wave
y = amplitude * math.sin(frequency * x + (wave_index * WAVE_OFFSET))
points.append((x, (y + (0.5 + wave_index)*wave_height)))
x += step_size
#print(f'Draw {len(points)} points for curve {num}')
if not MONOCHROME:
ctx.set_source_rgb(r, g, b)
else:
ctx.set_source_rgba(r, g, b, 1 - (alpha_step * num)) # make more transparent toward bottom
# make more transparent toward bottom
ctx.set_source_rgba(r, g, b, 1 - (alpha_step * wave_index))
# draw waves
ctx.move_to(*points[0])
for p in points[1:]:
@ -104,11 +105,12 @@ def create_wpotd(output):
ctx.line_to(*points[0])
ctx.fill()
lastpoints = points
#return surface
surface.write_to_png(output) # Output to PNG
return surface
#surface.write_to_png(output) # Output to PNG
def main():
create_wpotd('out/waves.png')
output = create_wpotd(1920, 1080)
output.write_to_png('out/waves.png')
if __name__ == '__main__':
main()

Loading…
Cancel
Save