for line in lines: if line[-1] !='\n' : line = line + '\n' if line[0] != 'd': fout.write(line) fout.write('d = '+str(datetime.date.today())) fout.close() ### Main Function r = Graph() r.init_rectgrid(Interval(m,n),include_corners=False,wrap=False,cellsize=1) init_r = 99 * [0] init_r.append(1) r.init_rvals([init_r]) t= History(r) #execfile(base_path+rule_fname) #fin = open(base_path+rule_fname) #test_string = fin.readlines() #fin.close() #exec(test_string) t.set_rule(base_path+rule_fname) t.set_params(param) t.generate(no_gen) t.set_color_dict(prop_colors) t.write_images(f_name,path)
from decodes.core import * from decodes.core import dc_color, dc_base, dc_vec, dc_point, dc_cs, dc_line, dc_mesh, dc_pgon, dc_xform import thesis from thesis.ants.ants import Graph, History from decodes.extensions.cellular_automata import CA import random import datetime t = History() t.add_gen() t.add_gen() r = Graph() r.init_rectgrid(Interval(3, 3), include_corners=False, wrap=False, cellsize=1) #r.init_rvals() # r.to_file() r.from_file() prop_values = (0, 1, 2) prop_colors = (Color(1, 1, 1), Color(1, 1, .5), Color(0)) state_list = ('undeveloped', 'access', 'built') no_states = len(state_list) color_dict = dict(zip(prop_values, prop_colors)) state_dict = dict(zip(prop_values, state_list)) sc = 1 #p = [1] m = 10 n = 10
from decodes.core import * from decodes.core import dc_color, dc_base, dc_vec, dc_point, dc_cs, dc_line, dc_mesh, dc_pgon, dc_xform import thesis from thesis.ants.ants import Graph, History from decodes.extensions.cellular_automata import CA import random import datetime t= History() t.add_gen() t.add_gen() r = Graph() r.init_rectgrid(Interval(3,3),include_corners=False,wrap=False,cellsize=1) #r.init_rvals() # r.to_file() r.from_file() prop_values = (0,1,2) prop_colors = (Color(1,1,1),Color(1,1,.5),Color(0)) state_list = ('undeveloped','access','built') no_states = len(state_list) color_dict = dict(zip(prop_values,prop_colors)) state_dict = dict(zip(prop_values, state_list)) sc = 1 #p = [1] m = 10
else: r.init_block(model_size=model_size,block_size=block_size, no_vals = param[10], increment = param[11]) r.to_csv(f_name,path) else: # r.init_ppm(init_fname,base_path+'\\maps\\',color_dict) r.from_csv(init_fname,base_path) p = r.parcel_list() footprint = r.parcel_fp(p[0], len(state_dict)) floor_area = r.parcel_flr(p[0], len(state_dict)) if out_fname != "": r.to_csv(out_fname,base_path) t= History(r) t.set_dict(color_dict,state_dict) t.set_rule(base_path+'\\rules\\'+rule_fname) t.set_vis(base_path+'\\rules\\'+vis_fname) t.set_params(param) t.generate(no_gen) if param[28] == 1 : t.write_svgs(f_name,path, display_size) t.hist[-1].neighbors(13,len(state_dict)) t.hist[-1].to_csv(f_name,path) t.write_parcels(f_name,path) t.write_parcels(f_name,path, len(t.hist)-1)
block_size=block_size, no_vals=param[10], increment=param[11]) r.to_csv(f_name, path) else: # r.init_ppm(init_fname,base_path+'\\maps\\',color_dict) r.from_csv(init_fname, base_path) p = r.parcel_list() footprint = r.parcel_fp(p[0], len(state_dict)) floor_area = r.parcel_flr(p[0], len(state_dict)) if out_fname != "": r.to_csv(out_fname, base_path) t = History(r) t.set_dict(color_dict, state_dict) t.set_rule(base_path + '\\rules\\' + rule_fname) t.set_vis(base_path + '\\rules\\' + vis_fname) t.set_params(param) t.generate(no_gen) if param[28] == 1: t.write_svgs(f_name, path, display_size) t.hist[-1].neighbors(13, len(state_dict)) t.hist[-1].to_csv(f_name, path) t.write_parcels(f_name, path) t.write_parcels(f_name, path, len(t.hist) - 1)
if block_size.a == 0: init_r = 30 * [0] init_r[0] = 1 r.init_rvals([init_r,[-1],[0]]) else: r.init_block(model_size,block_size, param[0]) r.to_csv(f_name,path) else: r.init_ppm(init_fname,base_path+'\\maps\\',color_dict) # r.from_csv(init_fname,base_path) if out_fname != "": r.to_csv(out_fname,base_path) t= History(r) t.set_rule(base_path+'\\rules\\'+rule_fname) t.set_vis(base_path+'\\rules\\'+vis_fname) t.set_params(param) t.generate(no_gen) t.set_color_dict(prop_colors) t.write_svgs(f_name,path, display_size,state_dict) def a_count(v,i,a): ret = 0 for j in a: if j[i] == v : ret += 1
r.init_block(model_size=model_size,block_size=block_size, no_vals = param[10], increment = param[11]) r.to_csv(f_name,path) else: # r.init_ppm(init_fname,base_path+'\\maps\\',color_dict) r.from_csv(init_fname,base_path) # # p = r.parcel_list() # footprint = r.parcel_fp(p[0], len(state_dict)) # floor_area = r.parcel_flr(p[0], len(state_dict)) # print "starting : ",footprint," far: ", floor_area # if out_fname != "": # r.to_csv(out_fname,base_path) t= History(r) t.set_dict(color_dict,state_dict) t.set_rule(base_path+'\\rules\\'+rule_fname) t.set_vis(base_path+'\\rules\\'+vis_fname) t.set_params(param) t.generate(no_gen, verbose = False) if param[28] == 1 : t.write_svgs(f_name,path, display_size) # t.hist[-1].neighbors(13,len(state_dict)) # t.hist[-1].to_csv(f_name,path) # t.write_parcels(f_name,path) if i == 0: # write initial condition
if line[-1] != '\n': line = line + '\n' if line[0] != 'd': fout.write(line) fout.write('d = ' + str(datetime.date.today())) fout.close() ### Main Function r = Graph() r.init_rectgrid(Interval(m, n), include_corners=False, wrap=False, cellsize=1) init_r = 19 * [0] + [1] #init_r = [0,1,2] r.init_rvals([init_r]) #r.to_svg("svg_out11",color_dict,cdim=Interval(1000,1000)) t = History(r) #execfile(base_path+rule_fname) #fin = open(base_path+rule_fname) #test_string = fin.readlines() #fin.close() #exec(test_string) t.set_rule(base_path + rule_fname) t.set_params(param) t.generate(no_gen) t.set_color_dict(prop_colors) t.write_svgs(f_name, path)