forked from protonphoton/LJ
827 lines
25 KiB
Python
827 lines
25 KiB
Python
#!/usr/bin/python3
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# -*- coding: utf-8 -*-
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# -*- mode: Python -*-
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'''
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Aurora Animations points generators
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LICENCE : CC
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Sam Neurohack
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"ScanH", "ScanV", "Wave", "Circle", "Dot00", "Zero", "Maxwell", "Starfield", "Trckr", "Word"
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'''
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import time, math, sys, os
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import numpy as np
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from scipy import signal
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from random import randrange, randint, random
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import live
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ljpath = r'%s' % os.getcwd().replace('\\','/')
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# import from shell
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sys.path.append(ljpath +'/../../libs3/')
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sys.path.append(ljpath +'/../libs3/')
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#import from LJ
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sys.path.append(ljpath +'/libs3/')
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sys.path.append('../libs3')
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sys.path.append(ljpath +'/../../libs3')
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import lj23layers as lj
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import gstt
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screen_size = [700,700]
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xy_center = [screen_size[0]/2,screen_size[1]/2]
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width = 700
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height = 700
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centerX = width / 2
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centerY = height / 2
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# 3D to 2D projection parameters
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fov = 256
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viewer_distance = 2.2
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# Useful variables init.
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white = lj.rgb2int(255,255,255)
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red = lj.rgb2int(255,0,0)
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blue = lj.rgb2int(0,0,255)
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green = lj.rgb2int(0,255,0)
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cyan = lj.rgb2int(255,0,255)
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yellow = lj.rgb2int(255,255,0)
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lifenb = 10
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'''
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# Animation parameters for each layer
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X = [{'coord': 0, 'rotspeed': 0, 'transpeed': 0, 'transmax': 0}] *3
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Y = [{'coord': 0, 'rotspeed': 0, 'transpeed': 0, 'transmax': 0}] *3
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Z = [{'coord': 0, 'rotspeed': 0, 'transpeed': 0, 'transmax': 0}] *3
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Layer = [{'scandots': 100, 'radius': 150, 'color': red, "run": True, "step":0, 'steps': 500, 'stepmax': 200, 'stepvals': [], 'lineSize': 300, 'intensity': 255}] * 3
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Xacc = 0.01
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Yacc = 0.01
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Zacc = 0.00
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'''
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#
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# Useful functions
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#
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def remap(s,min1,max1, min2, max2):
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a1, a2 = min1, max1
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b1, b2 = min2, max2
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return b1 + ((s - a1) * (b2 - b1) / (a2 - a1))
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minred = 0
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mingreen = 0
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minblue = 0
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maxz=50
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z = 20
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col = (255,255,255)
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def z2color(z, color):
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rgbcolor = int2rgb(color)
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#print()
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#print("z2color : z =", z, "color =",color,"rgb :", rgbcolor)
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newcolor = (z2range(z, rgbcolor[0], minred), z2range(z, rgbcolor[1], mingreen), z2range(z, rgbcolor[2], minblue))
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#print("newcolor :", newcolor)
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return rgb2int(newcolor)
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def rgb2int(rgb):
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return int('0x%02x%02x%02x' % tuple(rgb),0)
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def int2rgb(intcode):
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#hexcode = hex(intcode)[2:]
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hexcode = '{0:06X}'.format(intcode)
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return tuple(int(hexcode[i:i+2], 16) for i in (0, 2, 4))
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#return tuple(map(ord,hexcode[1:].decode('hex')))
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def z2range(z,color, mincolor):
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#print("z2range : z=", z, "maxz :",maxz,"component =",color, "mincolor =",mincolor)
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if color < mincolor:
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return mincolor
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a1, a2 = maxz,0
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b1, b2 = mincolor, color
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#print ("color component :", round(b1 + ((z - a1) * (b2 - b1) / (a2 - a1))))
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return round(b1 + ((z - a1) * (b2 - b1) / (a2 - a1)))
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def cc2range(s,min,max):
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a1, a2 = 0,127
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b1, b2 = min, max
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return b1 + ((s - a1) * (b2 - b1) / (a2 - a1))
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def range2cc(s,min,max):
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a1, a2 = min, max
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b1, b2 = 0,127
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return b1 + ((s - a1) * (b2 - b1) / (a2 - a1))
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def Proj(x, y, z, angleX, angleY, angleZ):
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rad = angleX * math.pi / 180
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cosa = math.cos(rad)
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sina = math.sin(rad)
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y2 = y
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y = y2 * cosa - z * sina
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z = y2 * sina + z * cosa
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rad = angleY * math.pi / 180
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cosa = math.cos(rad)
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sina = math.sin(rad)
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z2 = z
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z = z2 * cosa - x * sina
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x = z2 * sina + x * cosa
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rad = angleZ * math.pi / 180
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cosa = math.cos(rad)
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sina = math.sin(rad)
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x2 = x
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x = x2 * cosa - y * sina
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y = x2 * sina + y * cosa
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""" Transforms this 3D point to 2D using a perspective projection. """
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factor = fov / (viewer_distance + z)
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x = x * factor + centerX
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y = - y * factor + centerY
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return (x,y)
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def ssawtooth(samples, freq, phase, scale = 1):
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samparray = [0] * samples
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t = np.linspace(0+phase, 1+phase, samples)
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for ww in range(samples):
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samparray[ww] = signal.sawtooth(2 * np.pi * freq * t[ww]) * scale
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return samparray
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def ssquare(samples, freq, phase, scale = 1):
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samparray = [0] * samples
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t = np.linspace(0+phase, 1+phase, samples)
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for ww in range(samples):
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samparray[ww] = signal.square(2 * np.pi * freq * t[ww]) * scale
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return samparray
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def ssine(samples, freq, phase, scale = 1):
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samparray = [0] * samples
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t = np.linspace(0+phase, 1+phase, samples)
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for ww in range(samples):
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samparray[ww] = np.sin(2 * np.pi * freq * t[ww]) * scale
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return samparray
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def scos(samples, freq, phase, scale = 1):
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samparray = [0] * samples
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t = np.linspace(0+phase, 1+phase, samples)
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for ww in range(samples):
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samparray[ww] = np.cos(2 * np.pi * freq * t[ww]) * scale
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return samparray
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def slinear(samples, min, max):
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return np.linspace(min, max, samples)
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Range =0
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def rangelinear(samples, min, max):
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global Range
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samparray = []
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samparray.append(min)
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for sample in range(samples-2):
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samparray.append(Range+sample)
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samparray.append(max)
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if Range + samples-2 > max:
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Range = min
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Range += 1
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return sorted(samparray)
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def randlinear(samples, min, max):
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samparray = []
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for sample in range(samples):
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samparray.append(randrange(max))
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return sorted(samparray)
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# as randlinear but first min and last is max
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def randlinear2(samples, min, max):
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samparray = []
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samparray.append(min)
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for sample in range(samples-2):
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samparray.append(randrange(int(max)))
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samparray.append(max)
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return sorted(samparray)
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'''
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def slinear(samples, min, max):
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linearray = [0] * samples
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linearinc = (max-min)/samples
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for ww in range(samples):
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if ww == 0:
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linearray[ww] = min
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else:
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linearray[ww] = linearray[ww-1] + linearinc
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print ('linear :',linearray)
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return linearray
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'''
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def sbilinear(samples, min, max):
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samparray = [0] * samples
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half = round(samples/2)
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# UP : min -> max
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part = np.linspace(min,max, half)
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for ww in range(half):
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samparray[ww] = part[ww]
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# Down : max -> min
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part = np.linspace(max,min, half)
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for ww in range(half):
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samparray[half+ww] = part[ww]
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#print('linear min max', min, max)
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#print ('linear',samparray)
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return samparray
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#
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# FXs
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#
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'''
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Beatstep memory 2 Aurora simplex
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'''
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def ScanV(LAY):
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dots = []
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arr = randlinear2(LAY['scandots'],0, LAY['lineSize'])
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#arr = slinear(LAY['scandots'], LAY['lineSize'], 0)
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#print(arr)
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for y in arr:
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#print(y, LAY['lineSize'] )
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dots.append((0 + LAY['lineSize']/2, y - LAY['lineSize']/2, 0))
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return dots
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def ScanH(LAY):
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dots = []
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#print(slinear(LAY['scandots'], 0, LAY['lineSize']))
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for x in sbilinear(LAY['scandots']*2, LAY['lineSize'],0):
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dots.append((x , 0, 0))
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#print(dots)
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return dots
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def Wave(LAY):
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dots = []
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x = slinear(round(LAY['lineSize']), 0, LAY['lineSize'])
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y = ssine(round(LAY['lineSize']), LAY['wavefreq'], 0)
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for ww in range(round(LAY['lineSize'])):
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dots.append((50+x[ww], 50+y[ww] * LAY['radius'], 0))
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return dots
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def Circle(LAY):
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dots = []
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for angle in slinear(LAY['scandots'], 0, 360):
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rad = angle * math.pi / 180
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x = LAY['radius'] * math.cos(rad)
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y = LAY['radius'] * math.sin(rad)
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dots.append((x+LAY['lineSize']/2, y, 0))
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return dots
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def Word(LAY):
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lj.Text(LAY['word'], c = LAY['color'], layer = LAY['number'], xpos = LAY['Xcoord']+LAY['lineSize']/2, ypos = LAY['Ycoord'], resize = LAY['scale']*10, rotx = LAY['Xrotdirec'], roty = LAY['Yrotdirec'], rotz = LAY['Zrotdirec'])
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#lj.rPolyLineOneColor([(x/2,y/2),((x+1)/2,(y+1)/2)], c = LAY['color'], layer = l, xpos = 0, ypos = 0, resize = LAY['scale'], rotx = LAY['Xrotdirec'], roty = LAY['Yrotdirec'], rotz = LAY['Zrotdirec'])
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def Dot00(LAY):
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dots = []
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dots.append((0, 0, 0))
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return dots
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def Zero(LAY):
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dots = []
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return dots
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#
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# Starfields
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#
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def Onefield(LAY, Field, hori=0,verti=0):
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# starpoints = []
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#print(Field['displayedstars'], 'stars displayed')
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# Increase number of
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if Field['displayedstars'] < Field['num_stars'] and Field['starfieldcount'] % 15 == 0:
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Field['displayedstars'] += 1
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#if displayedstars == num_stars and starfieldcount % 10 == 0:
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# starspeed += 0.005
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#print starspeed
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for starnumber in range(0, Field['displayedstars']):
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# The Z component is decreased on each frame.
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Field['stars'][starnumber][2] -= Field['starspeed'] * 3
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# If the star has past the screen (I mean Z<=0) then we
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# reposition it far away from the screen (Z=max_depth)
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# with random X and Y coordinates.
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if Field['stars'][starnumber][2] <= 0:
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Field['stars'][starnumber][0] = randrange(-25,25)
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Field['stars'][starnumber][1] = randrange(-25,25)
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Field['stars'][starnumber][2] = Field['max_depth']
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# Convert the 3D coordinates to 2D using perspective projection.
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k = 128.0 / Field['stars'][starnumber][2]
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# Move Starfield origin.
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# if stars xpos/ypos is same sign (i.e left stars xpos is <0) than (joystick or code) acceleration (hori and verti moves the star field origin)
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if np.sign(Field['stars'][starnumber][0]) == np.sign(hori):
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x = int(Field['stars'][starnumber][0] * k + xy_center[0] + (hori*600))
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else:
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x = int(Field['stars'][starnumber][0] * k + xy_center[0] + (hori*500))
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if np.sign(Field['stars'][starnumber][1]) == np.sign(verti):
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y = int(Field['stars'][starnumber][1] * k + xy_center[1] + (verti*600))
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else:
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y = int(Field['stars'][starnumber][1] * k + xy_center[1] + (verti*500))
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# Add star to pointlist PL 0 if field display flag is true
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if 0 <= x < screen_size[0] - 2 and 0 <= y < screen_size[1] - 2:
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# print("adding star", str(x0)+","+str(y0), "to fields 0")
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#lj.PolyLineOneColor([(x0,y0),((x0+1),(y0+1))], c = Stars0Form.color, layer = Stars0Form.layer, closed = Stars0Form.closed)
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# print((x/2,y/2),((x+1)/2,(y+1)/2))
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#print( int2rgb(z2color(Field['stars'][starnumber][2], LAY['color'])))
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#lj.rPolyLineOneColor([(x/2,y/2),((x+1)/2,(y+1)/2)], c =LAY['color'], layer = LAY['number'], closed = False, xpos = 0, ypos = 0, resize = LAY['scale'], rotx = LAY['Xrotdirec'], roty = LAY['Yrotdirec'], rotz = LAY['Zrotdirec'])
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lj.rPolyLineOneColor([(x/2,y/2,0),((x+1)/2,(y+1)/2,0)], c = z2color(Field['stars'][starnumber][2], LAY['color']), layer = LAY['number'], closed = False, xpos = -200, ypos = 0, resize = LAY['scale'], rotx = LAY['Xrotdirec'], roty = LAY['Yrotdirec'], rotz = LAY['Zrotdirec'])
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#
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# Maxwell
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#
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'''
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Beatstep Encoders 3 :
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LX freq amp phasemod transamt RX freq amp phasemod rotdire
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LY freq amp phasemod transamt RL freq amp phasemod rotdire
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'''
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# sin:0/saw:33/squ:95/lin:127
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def MaxOneSide(LAY, Cux, Cuy, Cuz):
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#sines = ssine(LAY['scandots'], Cu['freq'], Cu['phasemod'], scale = Cu['amp'])
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#cosines = scos(LAY['scandots'], Cu['freq'], Cu['phasemod'], scale = Cu['amp'])
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#sines = ssine(LAY['scandots'], Cux['freq'], Cux['phaseoffset'], scale = Cux['amp'])
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#cosines = ssine(LAY['scandots'], Cux['freq'], Cux['phaseoffset'], scale = Cux['amp'])
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'''
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cosines = scos(LAY['scandots'], Cu['freq'], Cu['phase'], scale = Cu['amp'])
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saws = ssawtooth(LAY['scandots'], Cu['freq'], Cu['phase'], scale = Cu['amp'])
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sqrs = ssquare(LAY['scandots'], Cu['freq'], Cu['phase'], scale = Cu['amp'])
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'''
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dots = []
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#print("X", Cux['type'], Cux['phaseoffset'], Cux['inv'], Cux['amp'])
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if Cux['type'] ==0:
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xsteps = ssine(LAY['scandots'], Cux['freq'], Cux['phaseoffset'] + Cux['inv'], Cux['amp'])
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if Cux['type'] ==33:
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xsteps = ssawtooth(LAY['scandots'], Cux['freq'], Cux['phaseoffset'] + Cux['inv'], Cux['amp'])
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if Cux['type'] == 95:
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xsteps = ssquare(LAY['scandots'], Cux['freq'], Cux['phaseoffset'] + Cux['inv'], Cux['amp'])
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if Cux['type'] == 127:
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xsteps = slinear(LAY['scandots'], 0, Cux['amp'])
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#print("Y", Cuy['type'], Cuy['phaseoffset'], Cuy['inv'], Cuy['amp'])
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if Cuy['type'] ==0:
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ysteps = ssine(LAY['scandots'], Cuy['freq'], Cuy['phaseoffset'] + Cuy['inv'], Cuy['amp'])
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if Cuy['type'] ==33:
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ysteps = ssawtooth(LAY['scandots'], Cuy['freq'], Cuy['phaseoffset'] + Cuy['inv'], Cuy['amp'])
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if Cuy['type'] == 95:
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ysteps = ssquare(LAY['scandots'], Cuy['freq'], Cuy['phaseoffset'] + Cuy['inv'], Cuy['amp'])
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if Cuy['type'] == 127:
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ysteps = slinear(LAY['scandots'], 0, Cuy['amp'])
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#print("xsteps", xsteps)
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#print("ysteps", ysteps)
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for step in range(LAY['scandots']):
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# Cu['type'] sin:0/saw:33/squ:95/lin:127
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x = xsteps[step]
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y = ysteps[step]
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#x = sines[step]
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#y = cosines[step]
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dots.append((x, y, 0))
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return dots
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CurveLX = [{'type': 0, 'freq': 1, 'amp': 150, 'phasemod': 0, 'phaseoffset': 0, 'inv': 0}] * 3
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CurveLY = [{'type': 0, 'freq': 1, 'amp': 150, 'phasemod': 0, 'phaseoffset': 0, 'inv': np.pi/2}] * 3
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CurveLZ = [{'type': 0, 'freq': 1, 'amp': 150, 'phasemod': 0, 'phaseoffset': 0, 'inv': 0}] * 3
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CurveRX = [{'type': 0, 'freq': 1, 'amp': 150, 'phasemod': 0, 'phaseoffset': 0, 'inv': 0}] * 3
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CurveRY = [{'type': 0, 'freq': 1, 'amp': 150, 'phasemod': 0, 'phaseoffset': 0, 'inv': np.pi/2}] * 3
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CurveRZ = [{'type': 0, 'freq': 1, 'amp': 150, 'phasemod': 0, 'phaseoffset': 0, 'inv': 0}] * 3
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def Maxwell(LAY):
|
||
|
||
l =0
|
||
mixer = 0
|
||
|
||
dots = []
|
||
dotsL = MaxOneSide(LAY, CurveLX[l], CurveLY[l], CurveLZ[l])
|
||
dotsR = MaxOneSide(LAY, CurveRX[l], CurveRY[l], CurveRZ[l])
|
||
|
||
for dot in range(LAY['scandots']):
|
||
dotX = (dotsL[dot][0]*(100-mixer)/100) + (dotsR[dot][0]*mixer/100) #+ transX.values[point]
|
||
dotY = (dotsL[dot][1]*(100-mixer)/100) + (dotsR[dot][1]*mixer/100) #+ transY.values[point]
|
||
dotZ = (dotsL[dot][2]*(100-mixer)/100) + (dotsR[dot][2]*mixer/100) #+ transZ.values[point]
|
||
dots.append((dotX, dotY, dotZ))
|
||
return dots
|
||
'''
|
||
for dot in range(LAY['scandots']):
|
||
dotX = (dotsL[dot][0]*(100-LAY['mixer'])/100) + (dotsR[dot][0]*LAY['mixer']/100) #+ transX.values[point]
|
||
dotY = (dotsL[dot][1]*(100-LAY['mixer'])/100) + (dotsR[dot][1]*LAY['mixer']/100) #+ transY.values[point]
|
||
dotZ = (dotsL[dot][2]*(100-LAY['mixer'])/100) + (dotsR[dot][2]*LAY['mixer']/100) #+ transZ.values[point]
|
||
dots.append((dotX, dotY, dotZ))
|
||
'''
|
||
|
||
#
|
||
# Trckr
|
||
#
|
||
|
||
# get absolute face position points
|
||
def getPART(TrckrPts, pose_points):
|
||
|
||
dots = []
|
||
for dot in pose_points:
|
||
|
||
dots.append((TrckrPts[dot][0], TrckrPts[dot][1],0))
|
||
|
||
return dots
|
||
|
||
|
||
# Face keypoints
|
||
def face(TrckrPts):
|
||
pose_points = [0,1,2,3,4,5,6,7,8,9,10,11,12,13,14]
|
||
return getPART(TrckrPts, pose_points)
|
||
|
||
def browL(TrckrPts):
|
||
pose_points = [15,16,17,18]
|
||
return getPART(TrckrPts, pose_points)
|
||
|
||
def browR(TrckrPts):
|
||
pose_points = [22,21,20,19]
|
||
return getPART(TrckrPts, pose_points)
|
||
|
||
def eyeR(TrckrPts):
|
||
pose_points = [25,64,24,63,23,66,26,65,25]
|
||
return getPART(TrckrPts, pose_points)
|
||
|
||
def eyeL(TrckrPts):
|
||
pose_points = [28,67,29,68,30,69,31,28]
|
||
return getPART(TrckrPts, pose_points)
|
||
|
||
def pupR(TrckrPts):
|
||
pose_points = [27]
|
||
return getPART(TrckrPts, pose_points)
|
||
|
||
def pupL(TrckrPts):
|
||
pose_points = [32]
|
||
return getPART(TrckrPts, pose_points)
|
||
|
||
|
||
def nose1(TrckrPts):
|
||
pose_points = [62,41,33]
|
||
return getPART(TrckrPts, pose_points)
|
||
|
||
def nose2(TrckrPts):
|
||
pose_points = [40,39,38,43,37,42,36,35,34]
|
||
return getPART(TrckrPts, pose_points)
|
||
|
||
def mouth(TrckrPts):
|
||
pose_points = [50,49,48,47,46,45,44,55,54,53,52,51,50]
|
||
return getPART(TrckrPts, pose_points)
|
||
|
||
def mouthfull(TrckrPts):
|
||
pose_points = [50,49,48,47,46,45,44,55,54,53,52,51,50,59,60,61,44,56,57,58,50]
|
||
return getPART(TrckrPts, pose_points)
|
||
|
||
|
||
def Trckr(LAY, TrckrPts):
|
||
|
||
|
||
#lj.rPolyLineOneColor([(x/2,y/2),((x+1)/2,(y+1)/2)], c = LAY['color'], layer = l, closed = False, xpos = 0, ypos = 0, resize = LAY['scale'], rotx = LAY['Xrotdirec'], roty = LAY['Yrotdirec'], rotz = LAY['Zrotdirec'])
|
||
#print(LAY['scale'])
|
||
#print("browL", browL(), "browR", browR(), "nose1", nose1(), "mouth", mouth())
|
||
lj.rPolyLineOneColor(browL(TrckrPts), c = LAY['color'], layer = LAY['number'], closed = False, xpos = -200 +LAY['Xcoord'], ypos = LAY['Ycoord'], resize = LAY['scale']*0.8, rotx = LAY['Xrotdirec'], roty = LAY['Yrotdirec'], rotz = LAY['Zrotdirec'])
|
||
lj.rPolyLineOneColor(eyeL(TrckrPts), c = LAY['color'], layer = LAY['number'], closed = False, xpos = -200 +LAY['Xcoord'], ypos = LAY['Ycoord'], resize = LAY['scale']*0.8, rotx = LAY['Xrotdirec'], roty = LAY['Yrotdirec'], rotz = LAY['Zrotdirec'])
|
||
lj.rPolyLineOneColor(browR(TrckrPts), c = LAY['color'], layer = LAY['number'], closed = False, xpos = -200 +LAY['Xcoord'], ypos = LAY['Ycoord'], resize = LAY['scale']*0.8, rotx = LAY['Xrotdirec'], roty = LAY['Yrotdirec'], rotz = LAY['Zrotdirec'])
|
||
lj.rPolyLineOneColor(eyeR(TrckrPts), c = LAY['color'], layer = LAY['number'], closed = False, xpos = -200 +LAY['Xcoord'], ypos = LAY['Ycoord'], resize = LAY['scale']*0.8, rotx = LAY['Xrotdirec'], roty = LAY['Yrotdirec'], rotz = LAY['Zrotdirec'])
|
||
lj.rPolyLineOneColor(pupL(TrckrPts), c = LAY['color'], layer = LAY['number'], closed = False, xpos = -200 +LAY['Xcoord'], ypos = LAY['Ycoord'], resize = LAY['scale']*0.8, rotx = LAY['Xrotdirec'], roty = LAY['Yrotdirec'], rotz = LAY['Zrotdirec'])
|
||
lj.rPolyLineOneColor(pupR(TrckrPts), c = LAY['color'], layer = LAY['number'], closed = False, xpos = -200 +LAY['Xcoord'], ypos = LAY['Ycoord'], resize = LAY['scale']*0.8, rotx = LAY['Xrotdirec'], roty = LAY['Yrotdirec'], rotz = LAY['Zrotdirec'])
|
||
lj.rPolyLineOneColor(nose1(TrckrPts), c = LAY['color'], layer = LAY['number'], closed = False, xpos = -200 +LAY['Xcoord'], ypos = LAY['Ycoord'], resize = LAY['scale']*0.8, rotx = LAY['Xrotdirec'], roty = LAY['Yrotdirec'], rotz = LAY['Zrotdirec'])
|
||
lj.rPolyLineOneColor(nose2(TrckrPts), c = LAY['color'], layer = LAY['number'], closed = False, xpos = -200 +LAY['Xcoord'], ypos = LAY['Ycoord'], resize = LAY['scale']*0.8, rotx = LAY['Xrotdirec'], roty = LAY['Yrotdirec'], rotz = LAY['Zrotdirec'])
|
||
lj.rPolyLineOneColor(mouthfull(TrckrPts), c = LAY['color'], layer = LAY['number'], closed = False, xpos = -200 +LAY['Xcoord'], ypos = LAY['Ycoord'], resize = LAY['scale']*0.8, rotx = LAY['Xrotdirec'], roty = LAY['Yrotdirec'], rotz = LAY['Zrotdirec'])
|
||
|
||
|
||
|
||
|
||
#
|
||
# Butterfly
|
||
#
|
||
|
||
|
||
|
||
entities = []
|
||
|
||
for lifes in range(0,lifenb,1):
|
||
|
||
# 0: random posX, 1: random posY, 2: wing position, 3: Color, 4: XDirection
|
||
entities.append([randint(100,width-100), randint(100,height-100), random(), randint(45,16700000), randint(-2,2)])
|
||
|
||
|
||
print("entities", entities)
|
||
wingpos = random()
|
||
|
||
|
||
# One wing vertices
|
||
vertices = [
|
||
( 0.0 , 0.3603683 , 0.7174169 ), #1
|
||
( 0.0 , -4.39773 , 0.09228338 ), #2
|
||
( wingpos , 0.3603683 , 0.3174169 ), #3
|
||
( 0.0 , 0.3603683 , 0.7174169 ), #4
|
||
( -wingpos , 0.4115218 , 0.1858825 ), #7
|
||
( 0.0 , -4.39773 , 0.09228338 ) #2
|
||
]
|
||
'''
|
||
|
||
vertices = [
|
||
( 0.0 , -4.39773 , 0.7174169 ), # 1
|
||
( 0.0 , 4.39773 , 0.09228338 ), # 2
|
||
( wingpos , 0.3603683 , 0.3174169 ), # 3
|
||
( 0.0 , 0.3603683 , 0.7174169 ), # 4
|
||
( wingpos , -4.39773, 0.7174169 ), # 5
|
||
( 0.0 , -4.39773 , 0.7174169 ), # 6 = 1
|
||
( -wingpos ,-4.39773 , 0.1858825 ), #7
|
||
( 0.0 , 0.3603683 , 0.7174169 ), # 8
|
||
( -wingpos , 0.3603683 , 0.3174169 ), # 9
|
||
( 0.0 , 4.39773 , 0.09228338 ), # 10
|
||
]
|
||
'''
|
||
fov = 256
|
||
viewer_distance = 70.2
|
||
|
||
angleX = 0
|
||
angleY = 120
|
||
angleZ = 0
|
||
|
||
color = 0x101010
|
||
speed = 0
|
||
|
||
def Butterfly(LAY):
|
||
global angleX, angleY, angleZ
|
||
#angleX += 0.0
|
||
#angleY += 0.0
|
||
#angleZ += 0.0
|
||
|
||
for entity in entities:
|
||
#print(entity)
|
||
entity[0] += entity[4] + randint(-1,1) # change X/Y pos (Xdirection and little chaos)
|
||
if randint(0,20) > 15:
|
||
entity[1] += randint(-2,2)
|
||
|
||
centerX = entity[0]
|
||
centerY = entity[1]
|
||
# remember : z position is overall zoom
|
||
entity[2] += 1 # wings animation
|
||
if entity[2] > 10:
|
||
entity[2] = 0.0
|
||
wingpos = entity[2]
|
||
|
||
angleX = angleX # entity rotated in Z to follow Xdirection
|
||
angleY = angleY
|
||
|
||
if entity[4] > 0:
|
||
angleZ = (angleZ + entity[4]*18)
|
||
else:
|
||
angleZ = -(angleZ + entity[4]*18)
|
||
|
||
color = entity[3]
|
||
dots = []
|
||
verticecounter = 0
|
||
|
||
for v in vertices:
|
||
|
||
x = v[0]
|
||
y = v[1]
|
||
z = v[2]
|
||
if verticecounter == 2:
|
||
x = wingpos
|
||
if verticecounter == 4:
|
||
x = - wingpos
|
||
#print(x,y,z)
|
||
|
||
dots.append(Proj(x+entity[0], y+entity[1], z, angleX, angleY, angleZ))
|
||
verticecounter +=1
|
||
#print(dots)
|
||
|
||
lj.rPolyLineOneColor(dots, c = LAY['color'], layer = LAY['number'], closed = False, xpos = -300 +LAY['Xcoord'], ypos = -300+LAY['Ycoord'], resize = LAY['scale']*1.3, rotx = LAY['Xrotdirec'], roty = LAY['Yrotdirec'], rotz = LAY['Zrotdirec'])
|
||
|
||
'''
|
||
|
||
OBJECT Style
|
||
|
||
name, scandots, radius, color, run, step, steps, stepmax, stepvals, lineSize, intensity
|
||
L0 = LAYERobject("0", "saw", 100, 150, red, True, 0, 500, 200, [], 300, 255)
|
||
|
||
L0.name = name
|
||
L0.scandots = 100
|
||
L0.radius = 150
|
||
L0.color = red
|
||
L0.run = True
|
||
L0.step = 0,
|
||
L0.steps = 500,
|
||
L0.stepmax = 200
|
||
L0.stepvals =[]
|
||
L0.lineSize = 300
|
||
L0.intensity = 255
|
||
|
||
|
||
class LAYERobject:
|
||
|
||
def __init__(self, name, scandots, radius, color, run, step, steps, stepmax, stepvals, lineSize, intensity)
|
||
|
||
self.name = name
|
||
self.scandots = scandots
|
||
self.radius = radius
|
||
self.color = color
|
||
self.run = run
|
||
self.step = step
|
||
self.steps = steps
|
||
self.stepmax = stepmax
|
||
self.stepvals = stepvals
|
||
self.lineSize = lineSize
|
||
self.intensity = intensity
|
||
|
||
|
||
|
||
|
||
name, coord, rotspeed, ranspeed, transmax
|
||
X0 = COORDobject("X0",0, 0, 0, 0)
|
||
|
||
X0.name = "0"
|
||
X0.coord = 0
|
||
X0.rotspeed = 0
|
||
X0.transpeed = 0
|
||
X0.transmax = 0
|
||
|
||
class COORDobject:
|
||
|
||
def __init__(self, name, coord, rotspeed, ranspeed, transmax)
|
||
|
||
self.name = name
|
||
self.coord = coord,
|
||
self.rotspeed = rotspeed
|
||
self.transpeed = transpeed
|
||
self.transmax = transmax
|
||
|
||
|
||
#
|
||
# OLD STUFF not used
|
||
#
|
||
|
||
|
||
def AudioLissa():
|
||
global Xrot, Yrot, Zrot
|
||
|
||
levels = lj.fromRedis('/audiogen/levels')
|
||
# levels = r.get('/audiogen/levels')
|
||
#PL = 0
|
||
dots = []
|
||
amp = 200
|
||
nb_point = 60
|
||
|
||
Xrot += Xacc * 25
|
||
Yrot += Yacc * 25
|
||
Zrot += Zacc * 0
|
||
|
||
# scale = (380-viewgenbands2scrY(levels[0]))/300
|
||
#scale = (380 - (levels[0] * 4))/300
|
||
LissaObj.scale = float(levels[0]) / 55
|
||
print(type(float(levels[0])),levels[0], LissaObj.scale)
|
||
#print ("scale",scale)
|
||
#print ("scale",scale)
|
||
|
||
for t in range(0, nb_point+1):
|
||
y = 1 - amp*math.sin(2*math.pi*2*(float(t)/float(nb_point)))
|
||
x = 1 - amp*math.cos(2*math.pi*3*(float(t)/float(nb_point)))
|
||
#y = 1 - amp*math.sin(2*PI*cc2range(gstt.cc[5],0,24)*(float(t)/float(nb_point)))
|
||
#x = 1 - amp*math.cos(2*PI*cc2range(gstt.cc[6],0,24)*(float(t)/float(nb_point)))
|
||
|
||
dots.append((x,y))
|
||
|
||
# These points are generated in pygame coordinates space (0,0 is top left) defined by screen_size in globalVars.py
|
||
#lj23.PolyLineOneColor( dots, c = white, PL = PL, closed = False )
|
||
lj.rPolyLineOneColor(dots, c = LissaObj.color, PL = LissaObj.PL, closed = False , xpos = LissaObj.xpos, ypos = LissaObj.ypos, scale = LissaObj.scale, rotx = LissaObj.rotx, roty = LissaObj.roty , rotz = LissaObj.rotz)
|
||
|
||
|
||
|
||
|
||
# /X/0/coord
|
||
# /Layer/0/color
|
||
|
||
|
||
if path.find('/X') == 0:
|
||
command = path.split("/")
|
||
eval(command[0]+'['+str(command[1])+']['+command[2]+']='+args[0])
|
||
|
||
|
||
|
||
# increase/decrease a CC. Value can be positive or negative
|
||
def changeCC(value, path):
|
||
|
||
MaxwellCC = FindCC(path)
|
||
|
||
print(MaxwellCC, "CC :", FindCC(path),"was", gstt.ccs[gstt.lasernumber][MaxwellCC])
|
||
if gstt.ccs[gstt.lasernumber][MaxwellCC] + value > 127:
|
||
gstt.ccs[gstt.lasernumber][MaxwellCC] = 127
|
||
if gstt.ccs[gstt.lasernumber][MaxwellCC] + value < 0:
|
||
gstt.ccs[gstt.lasernumber][MaxwellCC] = 0
|
||
if gstt.ccs[gstt.lasernumber][MaxwellCC] + value < 127 and gstt.ccs[gstt.lasernumber][MaxwellCC] + value >0:
|
||
gstt.ccs[gstt.lasernumber][MaxwellCC] += value
|
||
|
||
print("maxwellccs changeCC in maxwellccs : path =", path, "CC :", FindCC(path), "is now ", gstt.ccs[gstt.lasernumber][MaxwellCC], "for laser", gstt.lasernumber)
|
||
cc(MaxwellCC, gstt.ccs[gstt.lasernumber][MaxwellCC] , dest ='to Maxwell 1')
|
||
|
||
|
||
|
||
def EncoderPlusOne(value, path = current["path"]):
|
||
if value < 50:
|
||
changeCC(1, path)
|
||
|
||
def EncoderMinusOne(value, path = current["path"]):
|
||
if value > 90:
|
||
changeCC(-1, path)
|
||
|
||
|
||
def EncoderPlusTen(value, path = current["path"]):
|
||
if value < 50:
|
||
changeCC(10, path)
|
||
|
||
def EncoderMinusTen(value, path = current["path"]):
|
||
if value > 90:
|
||
changeCC(-10, path)
|
||
|
||
|
||
'''
|