LJ/plugins/planetarium/lj3.py

# coding=UTF-8

'''
LJ v0.8.1 in python3
Some LJ functions useful for python clients (was framy.py)

OSC functions commented, waiting working on OSC in python3 

Config(redisIP, client number) 
PolyLineOneColor
rPolyLineOneColor

Text(word, color, PL, xpos, ypos, resize, rotx, roty, rotz) : Display a word
Send(adress,message) : remote control. See commands.py
WebStatus(message) : display message on webui
DrawPL(point list number) : once you stacked all wanted elements, like 2 polylines, send them to lasers.

LICENCE : CC
Sam Neurohack

'''

import math
import redis

# Import needed modules from osc4py3
from osc4py3.as_eventloop import *
from osc4py3 import oscbuildparse


#redisIP = '127.0.0.1'
#r = redis.StrictRedis(host=redisIP, port=6379, db=0)

ClientNumber = 0

point_list = []
pl = [[],[],[],[]]

#
# OSC interaction with LJ
#

def OSCstart():
	# Start the system.
	osc_startup()
	#osc_udp_client(redisIP, 8002, "LJ 8002")

def OSCframe():
	#print("OSCprocess")
	osc_process()

# Properly close the system. Todo
def OSCstop():
	osc_terminate()


def SendLJ(oscaddress,oscargs=''):
        
    try:
        msg = oscbuildparse.OSCMessage(oscaddress, None, [oscargs])
        osc_send(msg, "LJ 8002")
       	OSCframe()

    except:
        print ('Connection to LJ refused : died ?')
        pass

# Answer to LJ pings
def OSCping(value):

    print("I got /ping with value", value)
    SendLJ("/pong",value)

'''
def handlerfunction(s, x, y):
    # Will receive message data unpacked in s, x, y
    pass

def handlerfunction2(address, s, x, y):
    # Will receive message address, and message data flattened in s, x, y
    pass

# Make server channels to receive packets.
osc_udp_server("127.0.0.1", 3721, "localhost")
osc_udp_server("0.0.0.0", 3724, "anotherserver")
'''



ASCII_GRAPHICS = [

# caracteres corrects

	[(-50,30), (-30,-30), (30,-30), (10,30), (-50,30)],							#0
	[(-20,30), (0,-30), (-20,30)], 												#1
	[(-30,-10), (0,-30), (30,-10), (30,0), (-30,30), (30,30)],					#2
	[(-30,-30), (0,-30), (30,-10), (0,0), (30,10), (0,30), (-30,30)],				#3
	[(30,10), (-30,10), (0,-30), (0,30)],											#4
	[(30,-30), (-30,-30), (-30,0), (0,0), (30,10), (0,30), (-30,30)],				#5
	[(30,-30), (0,-30), (-30,-10), (-30,30), (0,30), (30,10), (30,0), (-30,0)],	#6
	[(-30,-30), (30,-30), (-30,30)],												#7
	[(-30,30), (-30,-30), (30,-30), (30,30), (-30,30), (-30,0), (30,0)],			#8
	[(30,0), (-30,0), (-30,-10), (0,-30), (30,-30), (30,10), (0,30), (-30,30)],	#9

# caracteres a implementer	
	[(-30,10), (30,-10), (30,10), (0,30), (-30,10), (-30,-10), (0,-30), (30,-10)], #:
	[(-30,-10), (0,-30), (0,30)], [(-30,30), (30,30)],							#;
	[(-30,-10), (0,-30), (30,-10), (30,0), (-30,30), (30,30)],					#<
	[(-30,-30), (0,-30), (30,-10), (0,0), (30,10), (0,30), (-30,30)],				#=
	[(30,10), (-30,10), (0,-30), (0,30)],											#>
	[(30,-30), (-30,-30), (-30,0), (0,0), (30,10), (0,30), (-30,30)],				#?
	[(30,-30), (0,-30), (-30,-10), (-30,30), (0,30), (30,10), (30,0), (-30,0)],	#@

# Caracteres corrects
	

	[(-30,30), (-30,-30), (30,-30), (30,30), (30,0), (-30,0)],				#A
	[(-30,30), (-30,-30), (30,-30), (30,30), (30,0), (-30,0)],				#A
	[(-30,30), (-30,-30), (30,-30), (30,30), (-30,30), (-30,0), (30,0)],		#B
	[(30,30), (-30,30), (-30,-30), (30,-30)],									#C
	[(-30,30), (-30,-30), (30,-30), (30,30), (-30,30)],						#D
	[(30,30), (-30,30), (-30,-0), (30,0), (-30,0), (-30,-30), (30,-30)],		#E
	[(-30,30), (-30,-0), (30,0), (-30,0), (-30,-30), (30,-30)],				#F
	[(0,0), (30,0), (30,30), (-30,30), (-30,-30),(30,-30)],					#G
	[(-30,-30), (-30,30), (-30,0), (30,0), (30,30), (30,-30)],				#H
	[(0,30), (0,-30)],														#I
	[(-30,30), (0,-30), (0,-30), (-30,-30), (30,-30)],						#J
	[(-30,-30), (-30,30), (-30,0), (30,-30), (-30,0), (30,30)],				#K
	[(30,30), (-30,30), (-30,-30)],											#L
	[(-30,30), (-30,-30), (0,0), (30,-30), (30,30)],							#M
	[(-30,30), (-30,-30), (30,30), (30,-30)],									#N
	[(-30,30), (-30,-30), (30,-30), (30,30), (-30,30)],						#O
	[(-30,0), (30,0), (30,-30), (-30,-30), (-30,30)],							#P
	[(30,30), (30,-30), (-30,-30), (-30,30), (30,30),(35,35)],				#Q
	[(-30,30), (-30,-30), (30,-30), (30,0), (-30,0), (30,30)],				#R
	[(30,-30), (-30,-30), (-30,0), (30,0), (30,30), (-30,30)],				#S
	[(0,30), (0,-30), (-30,-30), (30,-30)],									#T
	[(-30,-30), (-30,30), (30,30), (30,-30)],									#U
	[(-30,-30), (0,30), (30,-30)],											#V
	[(-30,-30), (-30,30), (0,0), (30,30), (30,-30)],							#W
	[(-30,30), (30,-30)], [(-30,-30), (30,30)],								#X
	[(0,30), (0,0), (30,-30), (0,0), (-30,-30)],								#Y
	[(30,30), (-30,30), (30,-30), (-30,-30)],									#Z
	
				# A implementer	

	[(-30,-10), (0,-30), (0,30)], [(-30,30), (30,30)],							#[
	[(-30,-10), (0,-30), (30,-10), (30,0), (-30,30), (30,30)],					#\
	[(-30,-30), (0,-30), (30,-10), (0,0), (30,10), (0,30), (-30,30)],				#]
	[(30,10), (-30,10), (0,-30), (0,30)],											#^
	[(30,-30), (-30,-30), (-30,0), (0,0), (30,10), (0,30), (-30,30)],				#_
	[(30,-30), (0,-30), (-30,-10), (-30,30), (0,30), (30,10), (30,0), (-30,0)],	#`
	
			# Implementé
	
	[(-20,20), (-20,-20), (20,-20), (20,20), (20,0), (-20,0)],				#a
	[(-20,20), (-20,-20), (20,-20), (20,20), (-20,20), (-20,0), (20,0)],		#b
	[(20,20), (-20,20), (-20,-20), (20,-20)],									#c
	[(-20,20), (-20,-20), (20,-20), (20,20), (-20,20)],						#d
	[(20,20), (-20,20), (-20,-0), (20,0), (-20,0), (-20,-20), (20,-20)],		#e
	[(-20,20), (-20,-0), (20,0), (-20,0), (-20,-20), (20,-20)],				#f
	[(0,0), (20,0), (20,20), (-20,20), (-20,-20),(20,-20)],					#g
	[(-20,-20), (-20,20), (-20,0), (20,0), (20,20), (20,-20)],				#H
	[(0,20), (0,-20)],														#I
	[(-20,20), (0,-20), (0,-20), (-20,-20), (20,-20)],						#J
	[(-20,-20), (-20,20), (-20,0), (20,-20), (-20,0), (20,20)],				#K
	[(20,20), (-20,20), (-20,-20)],											#L
	[(-20,20), (-20,-20), (0,0), (20,-20), (20,20)],							#M
	[(-20,20), (-20,-20), (20,20), (20,-20)],									#N
	[(-20,20), (-20,-20), (20,-20), (20,20), (-20,20)],						#O
	[(-20,0), (20,0), (20,-20), (-20,-20), (-20,20)],							#P
	[(20,20), (20,-20), (-20,-20), (-20,20), (20,20),(25,25)],				#Q
	[(-20,20), (-20,-20), (20,-20), (20,0), (-20,0), (20,20)],				#R
	[(20,-20), (-20,-20), (-20,0), (20,0), (20,20), (-20,20)],				#S
	[(0,20), (0,-20), (-20,-20), (20,-20)],									#T
	[(-20,-20), (-20,20), (20,20), (20,-20)],									#U
	[(-20,-20), (0,20), (20,-20)],											#V
	[(-20,-20), (-20,20), (0,0), (20,20), (20,-20)],							#W
	[(-20,20), (20,-20)], [(-20,-20), (20,20)],								#X
	[(0,20), (0,0), (20,-20), (0,0), (-20,-20)],								#Y
	[(20,20), (-20,20), (20,-20), (-20,-20)],									#Z

	[(-2,15), (2,15)]															# Point a la place de {
]

def Config(redisIP,client):
	global ClientNumber

	r = redis.StrictRedis(host=redisIP, port=6379, db=0)	
	ClientNumber = client
	osc_udp_client(redisIP, 8002, "LJ 8002")

# If you want to use rgb for color :
def rgb2int(r,g,b):
	return int('0x%02x%02x%02x' % (r,g,b),0)
 
def LineTo(xy, c, PL):
 
	pl[PL].append((xy + (c,)))

def Line(xy1, xy2, c, PL):
	LineTo(xy1, 0, PL)
	LineTo(xy2, c , PL)


def PolyLineOneColor(xy_list, c, PL , closed ):
	#print "--"
	#print "c",c
	#print "xy_list",xy_list
	#print "--"
	xy0 = None		
	for xy in xy_list:
		if xy0 is None:
			xy0 = xy
			#print "xy0:",xy0
			LineTo(xy0,0, PL)
			LineTo(xy0,c, PL)
		else:
			#print "xy:",xy
			LineTo(xy,c, PL)
	if closed:
		LineTo(xy0,c, PL)


# Computing points coordinates for rPolyline function from 3D and around 0,0 to pygame coordinates
def Pointransf(xy, xpos = 0, ypos =0, resize =1, rotx =0, roty =0 , rotz=0):

		x = xy[0] * resize
		y = xy[1] * resize
		z = 0

		rad = rotx * math.pi / 180
		cosaX = math.cos(rad)
		sinaX = math.sin(rad)

		y2 = y
		y = y2 * cosaX - z * sinaX
		z = y2 * sinaX + z * cosaX

		rad = roty * math.pi / 180
		cosaY = math.cos(rad)
		sinaY = math.sin(rad)

		z2 = z
		z = z2 * cosaY - x * sinaY
		x = z2 * sinaY + x * cosaY

		rad = rotz * math.pi / 180
		cosZ = math.cos(rad)
		sinZ = math.sin(rad)

		x2 = x
		x = x2 * cosZ - y * sinZ
		y = x2 * sinZ + y * cosZ

		#print xy, (x + xpos,y+ ypos)
		return (x + xpos,y+ ypos)
		'''
		to understand why it get negative Y
		
		# 3D to 2D projection
		factor = 4 * gstt.cc[22] / ((gstt.cc[21] * 8) + z)
		print xy, (x * factor + xpos,  - y * factor + ypos )
		return (x * factor + xpos,  - y * factor + ypos )
		'''

# Send 2D point list around 0,0 with 3D rotation resizing and reposition around xpos ypos
#def rPolyLineOneColor(self, xy_list, c, PL , closed, xpos = 0, ypos =0, resize =1, rotx =0, roty =0 , rotz=0):
def rPolyLineOneColor(xy_list, c, PL , closed, xpos = 0, ypos =0, resize =0.7, rotx =0, roty =0 , rotz=0):
	xy0 = None		
	for xy in xy_list:
		if xy0 is None:
			xy0 = xy
			LineTo(Pointransf(xy0, xpos, ypos, resize, rotx, roty, rotz),0, PL)
			LineTo(Pointransf(xy0, xpos, ypos, resize, rotx, roty, rotz),c, PL)
		else:
			LineTo(Pointransf(xy, xpos, ypos, resize, rotx, roty, rotz),c, PL)
	if closed:
		LineTo(Pointransf(xy0, xpos, ypos, resize, rotx, roty, rotz),c, PL)

 
def LinesPL(PL):
	print ("Stupido !! your code is to old : use DrawPL() instead of LinesPL()")
	DrawPL(PL)

def DrawPL(PL):
	#print '/pl/0/'+str(PL), str(pl[PL])
	if r.set('/pl/'+str(ClientNumber)+'/'+str(PL), str(pl[PL])) == True:
		pl[PL] = []
		return True
	else:
		return False

def ResetPL(self, PL):
	pl[PL] = []



def DigitsDots(number,color):
	dots =[]
	for dot in ASCII_GRAPHICS[number]:
		#print dot
		dots.append((gstt.xy_center[0]+dot[0],gstt.xy_center[1]+dot[1],color))
		#self.point_list.append((xy + (c,)))
	return dots

def CharDots(char,color):

	dots =[]
	for dot in ASCII_GRAPHICS[ord(char)-46]:
		dots.append((dot[0],dot[1],color))
	return dots

def Text(message, c, PL, xpos, ypos, resize, rotx, roty, rotz):

	dots =[]

	l = len(message)
	i= 0
	#print (message)
	
	for ch in message:
		
		#print ""
		# texte centre en x automatiquement selon le nombre de lettres l
		x_offset = 26 * (- (0.9*l) + 3*i)
		#print i,x_offset
		# if digit 
		if ord(ch)<58:
			char_pl_list = ASCII_GRAPHICS[ord(ch) - 48]
		else: 
			char_pl_list = ASCII_GRAPHICS[ord(ch) - 46 ]
			
		char_draw = []
		#dots.append((char_pl_list[0][0] + x_offset,char_pl_list[0][1],0))

		for xy in char_pl_list:
			char_draw.append((xy[0] + x_offset,xy[1],c))
		i += 1
		#print ch,char_pl_list,char_draw			
		rPolyLineOneColor(char_draw, c, PL , False, xpos, ypos, resize, rotx, roty, rotz)
		# print ("laser",PL,"message",message)
		#dots.append(char_draw)