[feat] drawing_optimisation: in progess

the feature implement a paper: https://art-science.org/journal/v7n4/v7n4pp155/artsci-v7n4pp155.pdf there is some generator to test the optimisation in: ./clitools/generators/drawingTests/ Now, all the optimisation will be in ./libs3/plotOptimizer.py in ./libs3/tracer3.py the adding of point is avoid an will be replace by the optimisation from the paper
2020-12-17 20:21:04 +01:00 · 2020-12-17 20:21:04 +01:00 · f3314441d3
parent 8164320694
commit f3314441d3
6 changed files with 493 additions and 27 deletions
--- a/clitools/generators/drawingTests/angleOptimization.py
+++ b/clitools/generators/drawingTests/angleOptimization.py
@ -0,0 +1,98 @@
 #!/usr/bin/python3
 # -*- coding: utf-8 -*-
 # -*- mode: Python -*-
 '''
 This generator print different angle form 0 to 180 degres
 v0.1.0
 LICENCE : CC
 by lapin (aka nipal)
 '''
 from __future__ import print_function
 import time
 import argparse
 import sys
 import math
 name="generator::endingPoint"
 def debug(*args, **kwargs):
    if( verbose == False ):
        return
    print(*args, file=sys.stderr, **kwargs)
 argsparser = argparse.ArgumentParser(description="dummy generator")
 argsparser.add_argument("-f","--fps",help="Frame Per Second",default=30,type=int)
 argsparser.add_argument("-s","--speed",help="point per frame progress",default=3,type=int)
 argsparser.add_argument("-v","--verbose",action="store_true",help="Verbose output")
 args        = argsparser.parse_args()
 fps=args.fps
 verbose=args.verbose
 optimal_looptime = 1 / fps
 debug(name+" optimal looptime "+str(optimal_looptime))
 width = 800
 height = 800
 white = 0xFFFFFF
 blank = 0
 radius = 100
 offset_circles = 10
 beg_angle = 0
 end_angle = 90
 offset_angle = 10
 angles_lines = []
 shape = []
 def set_angles_lines():
    margin = radius + offset_circles
    spacing_betwen = 2 * radius + offset_circles
    circles_per_line = math.floor((width - margin) / spacing_betwen)
    for ang in range(beg_angle, end_angle + offset_angle, offset_angle):
        nb = int(ang / offset_angle)
        cx = margin + (nb % circles_per_line) * spacing_betwen
        cy = margin + int(nb / circles_per_line) * spacing_betwen
        px = radius * math.cos(math.radians(ang))
        py = radius * math.sin(math.radians(ang))
        # line up
        angles_lines.append([-px + cx, py + cy, blank])
        angles_lines.append([-px + cx, py + cy, white])
        angles_lines.append([      cx,  2 + cy, white])
        angles_lines.append([ px + cx, py + cy, white])
        #angles_lines.append([ px + cx, py + cy, blank])
        # line down
        angles_lines.append([-px + cx, -py + cy, blank])
        angles_lines.append([-px + cx, -py + cy, white])
        angles_lines.append([      cx,  -2 + cy, white])
        angles_lines.append([ px + cx, -py + cy, white])
        #angles_lines.append([ px + cx, -py + cy, blank])
 set_angles_lines()
 shape = angles_lines
 # print(angles_lines)
 while True:
  start = time.time()
  print(shape, flush=True);
  looptime = time.time() - start
  if( looptime < optimal_looptime ):
    time.sleep( optimal_looptime - looptime)
    debug(name+" micro sleep:"+str( optimal_looptime - looptime))
--- a/clitools/generators/drawingTests/conected_component.py
+++ b/clitools/generators/drawingTests/conected_component.py
@ -0,0 +1,117 @@
 #!/usr/bin/python3
 # -*- coding: utf-8 -*-
 # -*- mode: Python -*-
 '''
 This generator print a shape with 3 discinected component, 2 non eulerian and one eulerian.
 v0.1.0
 LICENCE : CC
 by lapin (aka nipal)
 '''
 from __future__ import print_function
 import time
 import argparse
 import sys
 import math
 name="generator::endingPoint"
 def debug(*args, **kwargs):
    if( verbose == False ):
        return
    print(*args, file=sys.stderr, **kwargs)
 def debug2(*args, **kwargs):
    print(*args, file=sys.stderr, **kwargs)
 argsparser = argparse.ArgumentParser(description="dummy generator")
 argsparser.add_argument("-f","--fps",help="Frame Per Second",default=30,type=int)
 argsparser.add_argument("-s","--speed",help="point per frame progress",default=3,type=int)
 argsparser.add_argument("-v","--verbose",action="store_true",help="Verbose output")
 args        = argsparser.parse_args()
 fps=args.fps
 verbose=args.verbose
 optimal_looptime = 1 / fps
 debug(name+" optimal looptime "+str(optimal_looptime))
 width = 800
 height = 800
 white = 0xFFFFFF
 blank = 0
 def	shape_scale(shape, scale_factor):
 	new_shape = []
 	for p in shape:
 		new_shape.append([p[0] * scale_factor, p[1] * scale_factor, p[2]])
 	return new_shape
 def shape_incr(shape, x, y):
 	new_shape = []
 	for p in shape:
 		new_shape.append([p[0] + x, p[1] + y, p[2]])
 	return new_shape
 comp_a = []
 comp_b = []
 comp_c = []
 comp_b.append([ 0,  3, blank])
 comp_b.append([ 0,  4, white])
 comp_b.append([ 0,  0, white])
 comp_b.append([ 3,  0, white])
 comp_b.append([ 3,  6, white])
 comp_b.append([ 3,  6, white])
 comp_b.append([ 3,  0, white])
 comp_b.append([ 3,  0, blank])
 comp_b.append([ 3,  0, white])
 comp_b.append([ 5,  4, white])
 comp_b.append([ 5,  4, blank])
 comp_a.append([ 5, 17, blank])
 comp_a.append([ 5, 17, white])
 comp_a.append([ 0,  5, white])
 comp_a.append([12,  0, white])
 comp_a.append([17, 12, white])
 comp_a.append([ 5, 17, white])
 comp_a.append([ 5, 17, blank])
 comp_c.append([-3,  5, blank])
 comp_c.append([-3,  5, white])
 comp_c.append([ 0,  4, white])
 comp_c.append([ 0,  0, white])
 comp_c.append([ 4,  0, white])
 comp_c.append([ 4,  4, white])
 comp_c.append([ 7,  5, white])
 comp_c.append([ 7,  5, blank])
 comp_a = shape_scale(comp_a, 11)
 comp_a = shape_incr(comp_a, 300, 75)
 comp_b = shape_scale(comp_b, 45)
 comp_b = shape_incr(comp_b, 0, 300)
 comp_c = shape_scale(comp_c, 30)
 comp_c = shape_incr(comp_c, 600, 300)
 shape = comp_a + comp_b + comp_c
 while True:
  start = time.time()
  print(shape, flush=True);
  looptime = time.time() - start
  if( looptime < optimal_looptime ):
    time.sleep( optimal_looptime - looptime)
    debug(name+" micro sleep:"+str( optimal_looptime - looptime))
--- a/clitools/generators/drawingTests/endingPoint.py
+++ b/clitools/generators/drawingTests/endingPoint.py
@ -0,0 +1,77 @@
 #!/usr/bin/python3
 # -*- coding: utf-8 -*-
 # -*- mode: Python -*-
 '''
 This generator print 3 static vertical line.
 The aim is to show The aim is to show the laser beam ignition time.
 beam when ther is no optimisation
 v0.1.0
 LICENCE : CC
 by lapin (aka nipal)
 '''
 from __future__ import print_function
 import time
 import argparse
 import sys
 name="generator::endingPoint"
 def debug(*args, **kwargs):
    if( verbose == False ):
        return
    print(*args, file=sys.stderr, **kwargs)
 argsparser = argparse.ArgumentParser(description="dummy generator")
 argsparser.add_argument("-f","--fps",help="Frame Per Second",default=30,type=int)
 argsparser.add_argument("-s","--speed",help="point per frame progress",default=3,type=int)
 argsparser.add_argument("-v","--verbose",action="store_true",help="Verbose output")
 args        = argsparser.parse_args()
 fps=args.fps
 verbose=args.verbose
 optimal_looptime = 1 / fps
 debug(name+" optimal looptime "+str(optimal_looptime))
 white = 0xFFFFFF
 blank = 0
 offset_y = 100
 offset_x = 50
 begin_x = 200
 begin_y = 200
 shape_factor = [
        [0, 0, white],
        [0, 1, blank],
        [1, 1, white],
        [1, 0, blank],
        [2, 0, white],
        [2, 1, blank],
        [2, 1, blank],
 ]
 shape = []
 for point in shape_factor:
    shape.append([begin_x + offset_x * point[0],
                  begin_y + offset_y * point[1],
                  point[2]])
 while True:
  start = time.time()
  print(shape, flush=True);
  looptime = time.time() - start
  if( looptime < optimal_looptime ):
    time.sleep( optimal_looptime - looptime)
    debug(name+" micro sleep:"+str( optimal_looptime - looptime))
--- a/clitools/generators/drawingTests/order_optimization.py
+++ b/clitools/generators/drawingTests/order_optimization.py
@ -0,0 +1,84 @@
 #!/usr/bin/python3
 # -*- coding: utf-8 -*-
 # -*- mode: Python -*-
 '''
 This generator print a shape with best angle representation when the path is redraw
 v0.1.0
 LICENCE : CC
 by lapin (aka nipal)
 '''
 from __future__ import print_function
 import time
 import argparse
 import sys
 import math
 name="generator::endingPoint"
 def debug(*args, **kwargs):
    if( verbose == False ):
        return
    print(*args, file=sys.stderr, **kwargs)
 def debug2(*args, **kwargs):
    print(*args, file=sys.stderr, **kwargs)
 argsparser = argparse.ArgumentParser(description="dummy generator")
 argsparser.add_argument("-f","--fps",help="Frame Per Second",default=30,type=int)
 argsparser.add_argument("-s","--speed",help="point per frame progress",default=3,type=int)
 argsparser.add_argument("-v","--verbose",action="store_true",help="Verbose output")
 args        = argsparser.parse_args()
 fps=args.fps
 verbose=args.verbose
 optimal_looptime = 1 / fps
 debug(name+" optimal looptime "+str(optimal_looptime))
 width = 800
 height = 800
 white = 0xFFFFFF
 blank = 0
 point_offset = 250
 point_width  = 4
 point_list = [
 				[8,7,6,10,7,3,6,2,7,11,6,9],
 				[5,6,1,],
 				[4,7,12,],
 				]
 shape = []
 # on ajoute des lilste de point
 for l in point_list:
 	x = point_offset * ((l[0] - 1) % (point_width))
 	y = point_offset * int((l[0] - 1) / (point_width))
 	shape.append([x, y, blank])
 	debug2("=====")
 	debug2(f"id: {l[0]}\tx: {x}\ty: {y}\t\tpoint_width: {point_width}\t\n")
 	for p in l:
 		x = point_offset * ((p - 1) % (point_width))
 		y = point_offset * int((p - 1) / (point_width))
 		shape.append([x, y, white])
 		debug2(f"id: {p}\tx: {x}\ty: {y}\t\tpoint_width: {point_width}\t\n")
 while True:
  start = time.time()
  print(shape, flush=True);
  looptime = time.time() - start
  if( looptime < optimal_looptime ):
    time.sleep( optimal_looptime - looptime)
    debug(name+" micro sleep:"+str( optimal_looptime - looptime))
--- a/libs3/plotOptimizer.py
+++ b/libs3/plotOptimizer.py
@ -0,0 +1,93 @@
 class	Node:
 	def	__init__(self, sid, color):
 		self.sid = sid
 		self.connected = []
 		self.used = False
 		self.color = color
 		self.is_free = None	# may be an other value to initialise
 	def add_nodes(self, neighbord):
 		not_the_same = neighbord != self.sid
 		not_allrady_inside = neighbord not in self.connected
 		if neighbord != self.sid and neighbord not in self.connected:
 			self.connected.append(neighbord)
 	# print the content of the objet to debug with print()
 	def __repr__(self):
 		is_free = "  \t###" if self.is_free else "  \t___"
 		return  is_free + str(self.connected) + "\n"
 #class	Graph:
 #	nodes = {}	# dict of all nodes
 #
 #	def __init__(selt):
 #		pass
 def	list_to_nodes(pl):
 	all_nodes = {}				# it will contain all nodes
 	sid_prev = None
 	for p in pl:
 		sid = str([int(p[0]), int(p[1])])
 		is_colored = p[2] != 0
 		if is_colored:
 			if sid not in all_nodes:
 				all_nodes[sid] = Node(sid, p[2])
 			if sid_prev != None:	
 				all_nodes[sid].add_nodes(sid_prev)
 				all_nodes[sid_prev].add_nodes(sid)
 		sid_prev = sid if is_colored else None
 	return all_nodes
 # recursiv function witch get all connected node for one component and tag them as used
 def	get_one_comp(id_elem, nodes):
 	comp = []
 	comp.append(id_elem)
 	nodes[id_elem].used = True
 	for id_near in nodes[id_elem].connected:
 		if nodes[id_near].used == False:
 			comp += get_one_comp(id_near, nodes)
 	return comp
 def	get_comps(nodes):
 	comps = [] #all component
 	iter_nodes = iter(nodes)
 	nb_elem = len(nodes)
 	for id_nodes in iter_nodes:
 		if nodes[id_nodes].used == False:
 			comps.append(get_one_comp(id_nodes, nodes))
 	return comps
 # if ther is a class for the component it would be a good idea to set en atribute about eulerian graph or non eulerian graph
 def	set_free_vertices(components, nodes):
 	for comp in components:
 		all_even_neighbord = True
 		for id_node in comp:
 			if len(nodes[id_node].connected) % 2 == 0: # test if even neighbord
 				nodes[id_node].is_free = False
 			else:
 				nodes[id_node].is_free = True
 				all_even_neighbord = False
 		if all_even_neighbord:
 			for id_node in comp:
 				nodes[id_node].is_free = True
 def	optimizer(pl):
 	all_nodes = {}				# it will contain all nodes
 	components = []	# list of connected node as a graph
 	# construct dict of connected all_nodes
 	all_nodes = list_to_nodes(pl)
 	components = get_comps(all_nodes)
 	set_free_vertices(components, all_nodes)
 	print("\n\nall_nodes:\n", all_nodes)
 	print("\n\nconnected_components:\n", components)
 	return pl
 if __name__ == '__main__':
 	pl = [(355, 262, 0), (355, 262, 16777215), (300, 130, 16777215), (432, 75, 16777215), (487, 207, 16777215), (355, 262, 16777215), (355, 262, 0), (0, 435, 0), (0, 480, 16777215), (0, 300, 16777215), (135, 300, 16777215), (135, 570, 16777215), (135, 570, 16777215), (135, 300, 16777215), (135, 300, 0), (135, 300, 16777215), (225, 480, 16777215), (225, 480, 0), (510, 450, 0), (510, 450, 16777215), (600, 420, 16777215), (600, 300, 16777215), (720, 300, 16777215), (720, 420, 16777215), (810, 450, 16777215), (810, 450, 0)]
 	optimizer(pl)
--- a/libs3/tracer3.py
+++ b/libs3/tracer3.py
@ -81,7 +81,8 @@ import pdb
 import ast
 import redis
-from libs3 import homographyp
+from libs3 import homographyp, plotOptimizer as po
 import numpy as np
 import binascii
@ -223,43 +224,39 @@ class DAC(object):
 		while True:
-			#pdb.set_trace()    
+			self.pl = po.optimizer(self.pl)
 			for indexpoint,currentpoint in enumerate(self.pl):
-				#print indexpoint, currentpoint
+
 				# transformations des point au format adapter au etherdream
 				xyc = [currentpoint[0],currentpoint[1],currentpoint[2]]
 				self.xyrgb = self.EtherPoint(xyc)
 				#print(self.xyrgb[2:])
 				rgb = (round(self.xyrgb[2:][0] *self.intred/100), round(self.xyrgb[2:][1] *self.intgreen/100), round(self.xyrgb[2:][2] *self.intblue/100))
 				#print("rgb :", rgb)
-				#round(*self.intred/100) 
+				yield self.xyrgb
-				#round(*self.intgreen/100)
+				##**//# ajout de point pour un tracer adapter
-				#round(*self.intblue/100)
+				##**//delta_x, delta_y = self.xyrgb[0] - self.xyrgb_prev[0], self.xyrgb[1] - self.xyrgb_prev[1]
-				
+				##**//#test adaptation selon longueur ligne
-				delta_x, delta_y = self.xyrgb[0] - self.xyrgb_prev[0], self.xyrgb[1] - self.xyrgb_prev[1]
+				##**//if math.hypot(delta_x, delta_y) < 4000:
 				#test adaptation selon longueur ligne
 				if math.hypot(delta_x, delta_y) < 4000:
-					# For glitch art : decrease lsteps
+				##**//	# For glitch art : decrease lsteps
-					#l_steps = [ (1.0, 8)]
+				##**//	#l_steps = [ (1.0, 8)]
-					l_steps = gstt.stepshortline
+				##**//	l_steps = gstt.stepshortline
-				else:
+				##**//else:
-					# For glitch art : decrease lsteps
+				##**//	# For glitch art : decrease lsteps
-					#l_steps = [ (0.25, 3), (0.75, 3), (1.0, 10)]
+				##**//	#l_steps = [ (0.25, 3), (0.75, 3), (1.0, 10)]
-					l_steps = gstt.stepslongline
+				##**//	l_steps = gstt.stepslongline
-				for e in l_steps:
+				##**//for e in l_steps:
-					step = e[0]
+				##**//	step = e[0]
-					for i in range(0,e[1]):
+				##**//	for i in range(0,e[1]):
-						self.xyrgb_step = (self.xyrgb_prev[0] + step*delta_x, self.xyrgb_prev[1] + step*delta_y) + rgb # + self.xyrgb_prev[2:]# + rgb
+				##**//		self.xyrgb_step = (self.xyrgb_prev[0] + step*delta_x, self.xyrgb_prev[1] + step*delta_y) + rgb # + self.xyrgb_prev[2:]# + rgb
-						#print(self.xyrgb_step)
+				##**//		#print(self.xyrgb_step)
-						yield self.xyrgb_step
+				##**//		yield self.xyrgb_step
-				self.xyrgb_prev = self.xyrgb
+				##**//self.xyrgb_prev = self.xyrgb
 	def GetPoints(self, n):