def update_tree(GP_prog):
import initGlobal as init
import update_state as us
anten = init.AnT()
Sub = init.Sub()
L = init.L()
U = init.U()
low = init.lowlevel()
GP = init.GP()
#path = us.load_temporary_path()
us.update_all_saved_parameters(anten, Sub, L, U, GP, low)
# calculate all of edge of substrate.
GP_prog.childs[0].childs[0].valueofnode = []
for i in range(3):
GP_prog.childs[0].childs[0].valueofnode.append(
GP_prog.childs[0].childs[0].childs[i].valueofnode)
temp = GP_prog.childs[0].childs[0].valueofnode
GP_prog.childs[0].valueofnode = []
for i in range(3):
# calculate all of the real substrate's parameters.
if i == 0:
temp2 = round(((temp[i] + 1) / 2) *
(Sub.rangeOx[1] - Sub.rangeOx[0]) + Sub.rangeOx[0],
4) # Ox edge
elif i == 1:
temp2 = round(((temp[i] + 1) / 2) *
(Sub.rangeOy[1] - Sub.rangeOy[0]) + Sub.rangeOy[0],
4) # Oy edge.
else:
temp2 = round(((temp[i] + 1) / 2) *
(Sub.rangeOz[1] - Sub.rangeOz[0]) + Sub.rangeOz[0],
4) # Oz edge.
GP_prog.childs[0].valueofnode.append(temp2)
# Secondly create patterns.
MaxX = GP_prog.childs[0].valueofnode[
0] - Sub.decrease ### real MaxX,Y are decreased 1mm before to create
# any pattern unit(like L1,U1,U2,...).
MaxY = GP_prog.childs[0].valueofnode[1] - Sub.decrease
Zsize = GP_prog.childs[0].valueofnode[2]
GP_prog.substrate_size = [MaxX + Sub.decrease, MaxY + Sub.decrease, Zsize]
GP_prog.childs[1].childs[0].childs[0] = gp.updateFullBlueTree(
GP_prog.childs[1].childs[0].childs[0], [MaxX, MaxY], 5)
GP_prog.childs[1].childs[0].valueofnode = gp.get_val_frombluetree(
copy.deepcopy(GP_prog.childs[1].childs[0].childs[0]))
GP_prog.childs[1].valueofnode = GP_prog.childs[1].childs[0].valueofnode
return GP_prog
def lowlevel_optimizer(ind, state, pop_num):
# the inputs: - IND individual
# - STATE
# - POP_NUM the specified ID of current individual which be optimized in here.
import initGlobal as init
import update_state as us
lowinit = init.lowlevel()
ant = init.AnT()
inGP = init.GP(
) # get the essential parameters of GP process from initGlobal.py file. note: this's global parameter.
if init.Re_trainning:
ant = init.AnT()
Sub = init.Sub()
L = init.L()
U = init.U()
lowinit = init.lowlevel()
GP = init.GP()
#path = us.load_temporary_path()
us.update_all_saved_parameters(ant, Sub, L, U, GP, lowinit)
else:
us.update_path_low(ant, lowinit)
anpha = lowinit.anpha
saved_tree = [
] # save all of the current tree generated by all of the directions
for i in range(lowinit.number_direction):
saved_tree.append([])
state.lowlevel = True
global_name = lowinit.tmpDir + ant.Antenna_Name + 'lowlevel_gen_'
global_tabname = lowinit.tmpTab + ant.Antenna_Name + '_gen_'
print('running low-level optimizer for generation ', state.gen,
'population ', pop_num)
chromosome, subtree_chrom, IDlist = hp.getChrom(
ind) # get chromosome from tree and other atributes.
num = len(chromosome) # number of values will be optimized.
# create randomly the trainning data for ANN.
y = [] # to save all of the fitness of each direction.
for i in range(lowinit.number_direction):
y.append([])
state.current_low_fitness = y
fitness = ind.fitness # save original chromosome fitness.
return_loss = []
return_loss.append(ind.ReturnLoss) # save original return loss variable.
for i in range(lowinit.number_direction):
return_loss.append([])
X_training = np.zeros(
(lowinit.number_direction,
num)) # X_training in this case used for direct search method.
d = X_training # init the matrix of the directions.
current_chromosome = np.zeros(num)
for i in range(
num
): # save original chromosome, where this point is the start point as well as the x0 point.
current_chromosome[i] = chromosome[i]
for i in range(
lowinit.number_direction): # create the matrix of the direction.
for ii in range(num):
d[i][ii] = round(random.uniform(
-1, 1), 4) # X_training in this case is the matrix direction.
#print(X_training)
########################################################################################################################
########################################################################################################################
for k in range(lowinit.number_search_step):
state.lowlevel_k = k
# now update the x_k follow each of direction.
for i in range(lowinit.number_direction):
for ii in range(num):
X_training[i][ii] = current_chromosome[ii] + anpha * d[i][ii]
if X_training[i][ii] > 1:
X_training[i][ii] = 1
if X_training[i][ii] < -1:
X_training[i][ii] == -1
# generate all of the scripts.
print('generating ', lowinit.number_direction,
' scripts in low lelvel optimizer in generation ', state.gen)
'''
# before run the next generation, all of the tab file need be deleted.
filelist = [ f for f in os.listdir(lowinit.tmpTab) if f.endswith(".tab") ]
for f in filelist:
os.remove(os.path.join(lowinit.tmpTab, f))
# be fore run the next gen, all of the hfss file in temp need be deleted.
filelist = [ f for f in os.listdir(lowinit.tmpDir) if (f.endswith(".hfss") or f.endswith(".vbs") or f.endswith(".txt"))]
for f in filelist: # delete all before files.
os.remove(os.path.join(lowinit.tmpDir, f))'''
########################################################
############## insert chromosome.
# create temporary population to save current new individual.
#pop = []
#for i in range(lowinit.number_direction):
# tree = hp.insert_chrom(ind.tree,X_training[i,:],subtree_chrom, IDlist)
#tree_temp = hp.insert_chrom(ind.tree,X_training[2,:],subtree_chrom, IDlist)
for i in range(lowinit.number_direction):
tree = hp.insert_chrom(ind.tree, X_training[i, :], subtree_chrom,
IDlist)
#if i != 2:
# if tree == tree_temp:
# raise
#pop[i].tree.childs[1].valueofnode.plot()
[Substrate, polygons,
centroid, poly_list, poly_list_type] = hp.get_all_para_for_hfss(
tree) # get necessary parameters for genscript function.
name = global_name + str(state.gen) + '_pop_' + str(
state.population_num) + '_step_k' + str(k) + '_d_' + str(
i) # name of directory would
# be used to save .vbs and .hfss file.
tabname = global_tabname + str(state.gen) + '_pop_' + str(
state.population_num) + '_step_k' + str(k) + '_d_' + str(
i) # name of directory
# would be used to save .tab file.
temppp.tree = tree
temppp.nodelist = ind.nodelist
temp, _, _ = hp.getChrom(temppp)
print(X_training[i, :])
print(".....")
print(temp)
for iiii in range(len(X_training[i, :])):
if not (
X_training[i, iiii] == temp[iiii]
): # this part is to test the insert and getchrom function.
raise
genscript(Substrate, polygons, centroid, name + '.vbs', tabname,
name + '.hfss', poly_list, poly_list_type)
f = open(name + '.txt', 'w')
f.write(hp.tree2str(tree))
f.close()
saved_tree[i] = tree
del tree
del Substrate
del polygons
del centroid
#raise ValueError("Finished testing")
#######
# running all of the scripts.
nameDir = global_name + str(state.gen) + '_pop_' + str(
state.population_num) + '_step_k' + str(
k) + '_d_' # file name direction of the vbs file.
hrun.RunPopScript(lowinit.number_direction, nameDir, 0,
len(init.PCnames), state)
# getting the fitness of each
for i in range(lowinit.number_direction):
spec_nameDir_tab = global_tabname + str(state.gen) + '_pop_' + str(
state.population_num) + '_step_k' + str(k) + '_d_' + str(
i) + '.tab'
[m, n, p, q] = hrun.assignFitness(spec_nameDir_tab, state.gen)
print('i ', i, '___', m)
[y[i], return_loss[i]] = [m, n]
if m < inGP.desired_fitness:
shutil.copy2(
global_name + str(state.gen) + '_pop_' +
str(state.population_num) + '_step_k' + str(k) + '_d_' +
str(i) + '.vbs', ant.resultsDir)
shutil.copy2(spec_nameDir_tab, ant.resultsDir)
shutil.copy2(
global_name + str(state.gen) + '_pop_' +
str(state.population_num) + '_step_k' + str(k) + '_d_' +
str(i) + '.txt', ant.resultsDir)
#hp.drawtree(pop[i].tree,ant.resultsDir + '_gen_' + str(gen) + '_pop_' + str(i))
f = open(
ant.resultsDir + 'lowlevel_gen_' + str(state.gen) +
'_pop_' + str(state.population_num) + '_step_k' + str(k) +
'_d_' + str(i) + '.txt', 'w')
#f.write(hp.tree2str(saved_tree[i]))
#f.write('#')
f.write('fitness: ' + str(m))
f.write('#')
if p:
f.write("_____exist best fitness")
if q:
f.write("___ that is better than overcome_desired")
#f.write('time: ' + str((time.time() - first_time)/60))
f.close()
###
fitness_k = min(y)
index = y.index(fitness_k)
if fitness_k < fitness:
for i in range(num):
current_chromosome[i] = X_training[index][i]
fitness = fitness_k
else:
anpha = anpha * lowinit.shrink # shrink the anpha maybe because the stepsize is a little big.
# np.savetxt('C:\\Opt_files\\lowlevel\\y.txt',y,delimiter = ',')
# np.savetxt('C:\\Opt_files\\lowlevel\\X.txt',X_training,delimiter = ',')
ind.fitness = fitness
ind.tree = hp.insert_chrom(ind.tree, current_chromosome, subtree_chrom,
IDlist)
state.lowlevel = False
#del saved_tree
return ind
def makeGP_prog(maxSub, maxPat, maxBlue, ismaxdep):
# makeGP_prog makes a entire GP tree.
# whre maxSub: the maximum depth of the genSub sub-tree.
# maxPat: the maximum depth of the genPat sub-tree.
# maxBlue: the maximum depth of the Blue sub-tree.
# ismaxdep: specify whether GP tree will be created with maxdepth of all branch or not.
GP_prog = gp.node()
Sub = init.Sub()
if init.Re_trainning:
import update_state as us
anten = init.AnT()
Sub = init.Sub()
L = init.L()
U = init.U()
low = init.lowlevel()
GP = init.GP()
#path = us.load_temporary_path()
us.update_all_saved_parameters(anten, sub, L, U, GP, low)
GP_prog.strname = 'GP_prog'
GP_prog.childs = []
GP_prog.funcORter = 'func'
# firstly need to create the substrate tree.
if maxSub == 1:
# create addsub3 tree.
gensub1 = gp.node()
gensub1.strname = 'gensub1'
gensub1.type = 4
gensub1.childs = []
gensub1.childs.append(gp.addsub3())
gensub1.funcORter = 'func'
GP_prog.childs.append(gensub1)
else: # when maxSub != 1.
pass
# calculate all of edge of substrate.
GP_prog.childs[0].childs[0].valueofnode = []
for i in range(3):
GP_prog.childs[0].childs[0].valueofnode.append(
GP_prog.childs[0].childs[0].childs[i].valueofnode)
temp = GP_prog.childs[0].childs[0].valueofnode
GP_prog.childs[0].valueofnode = []
for i in range(3):
# calculate all of the real substrate's parameters.
if i == 0:
temp2 = round(((temp[i] + 1) / 2) *
(Sub.rangeOx[1] - Sub.rangeOx[0]) + Sub.rangeOx[0],
4) # Ox edge
elif i == 1:
temp2 = round(((temp[i] + 1) / 2) *
(Sub.rangeOy[1] - Sub.rangeOy[0]) + Sub.rangeOy[0],
4) # Oy edge.
else:
temp2 = round(((temp[i] + 1) / 2) *
(Sub.rangeOz[1] - Sub.rangeOz[0]) + Sub.rangeOz[0],
4) # Oz edge.
GP_prog.childs[0].valueofnode.append(temp2)
# Secondly create patterns.
MaxX = GP_prog.childs[0].valueofnode[
0] - Sub.decrease ### real MaxX,Y are decreased 1mm before to create
# any pattern unit(like L1,U1,U2,...).
MaxY = GP_prog.childs[0].valueofnode[1] - Sub.decrease
Zsize = GP_prog.childs[0].valueofnode[2]
GP_prog.substrate_size = [MaxX + Sub.decrease, MaxY + Sub.decrease, Zsize]
[tree, lastnode] = gp.makeBlueTree(maxBlue, ismaxdep, 0, MaxX, MaxY)
fullbluetree = gp.genFullBlueTree(tree)
fullbluetree = gp.updateFullBlueTree(fullbluetree, [MaxX, MaxY], 1)
if maxPat == 1:
# create
genpat1 = gp.node()
genpat1.strname = 'genpat1'
genpat1.type = 5
genpat1.childs = []
bluetree1 = gp.node()
bluetree1.strname = 'bluetree1'
bluetree1.type = 2
bluetree1.funcORter == 'func'
bluetree1.childs = []
bluetree1.childs.append(fullbluetree)
genpat1.childs.append(bluetree1)
genpat1.funcORter = 'func'
GP_prog.childs.append(genpat1)
GP_prog.childs[1].childs[0].valueofnode = gp.get_val_frombluetree(
copy.deepcopy(fullbluetree))
GP_prog.childs[1].valueofnode = GP_prog.childs[1].childs[0].valueofnode
return GP_prog
import InitPopMethods as initpop
import initGlobal as init
import Helper as hp
inGP = init.GP()
[a, b] = initpop.NewInd(0, inGP.maxSub, inGP.maxPat, inGP.maxBlue, False)
hp.drawtree(a.tree)
hp.drawNodeIDs(a.tree)
print(a.nodelist.redlist)
print(a.nodelist.subbluelist)
a.tree.childs[1].valueofnode.plot()
pop = initpop.rampinit(5, inGP.maxSub, inGP.maxPat, inGP.maxBlue, 0.6)
for i in range(len(pop)):
print(pop[i].id)
print(pop[i].tree.MaxXY)
hp.drawtree(pop[i].tree)
hp.drawNodeIDs(pop[i].tree)
pop[i].tree.childs[1].valueofnode.plot()
filelist = [
f for f in os.listdir(mydir_hfss)
if (f.endswith(".hfss") or f.endswith(".vbs") or f.endswith(".txt"))
]
for f in filelist: # delete all before files.
os.remove(os.path.join(mydir_hfss, f))
class state: # define a state object to save some necessary results.
pass
#import os
state.lowlevel = False
state.best_hisFitness = []
inGP = init.GP(
) # get the essential parameters of GP process from initGlobal.py file. note: this's global parameter.
gen = 1 # current generation.
pop = initpop.rampinit(inGP.numpop, inGP.maxSub, inGP.maxPat, inGP.maxBlue,
inGP.rate) #-- init population by rampinit method.
global_name = inAnT.tmpDir + inAnT.Antenna_Name + '_gen_'
global_tabname = inAnT.tmpTab + inAnT.Antenna_Name + '_gen_'
for iii in range(inGP.numgen):
state.gen = gen
# before run the next generation, all of the tab file need be deleted.
filelist = [f for f in os.listdir(mydir) if f.endswith(".tab")]
for f in filelist:
os.remove(os.path.join(mydir, f))
# be fore run the next gen, all of the hfss file in temp need be deleted.
def genscript(Substrate,polygons,centroid,tmpScriptFile,outFile,hfssFile,poly_list,poly_list_type):
import initGlobal as init
anten = init.AnT()
sub = init.Sub()
# this function create the vbs file.
# input arguments:
# - Substrate: the list of edges of the substrate.
# - polygons: the list of all coordinates to help draw the patch. Got from the second output of
# Helper.get_all_para_for_hfss() function.
if init.Re_trainning:
import update_state as us
anten = init.AnT()
sub = init.Sub()
L = init.L()
U = init.U()
low = init.lowlevel()
GP = init.GP()
us.update_all_saved_parameters(anten, sub, L, U, GP, low)
addition_number = sub.addition # increase the range of substrate.
# frequency
c = anten.c
fC = anten.fC
fStart = anten.fStart
fStop = anten.fStop
npoints = anten.npoints
Lambda = (c/fC)*1000
# radiation boundaries.
#AirX = Nx*dAnt + Lambda/2
#AirY = Ny*dAnt + Lambda/2
AirZ = Lambda + Substrate[2] + 5 # 5 is the length of the coaxial cable.
# solution parameters (GHz)
# define some attributes of substrate.
startX = centroid[0] - ((Substrate[0]+addition_number)/2) # the X original coordinate helps to draw the substrate.
startY = centroid[1] - ((Substrate[1]+addition_number)/2) # the Y original coordinate helps to draw the substrate.
length_W = Substrate[0] + addition_number # imply that it is the width_ox
length_L = Substrate[1] + addition_number # imply that it is the length_oy
centroidX_substrate = startX + length_W/2 # is the ox centroid coordinate of the substrate.
centroidY_substrate = startY + length_L/2 # is the oy centroid coordinate of the substrate.
####
x_coaxial_cable_coordinate = centroidX_substrate + (length_W/2)/3.5
y_coaxial_cable_coordinate = centroidY_substrate
coaxial_check = geose.Point(x_coaxial_cable_coordinate,y_coaxial_cable_coordinate)
checking = 0
for i in range(len(polygons)):
if poly_list[i].intersects(coaxial_check)[0]:
checking = checking + 1
if checking == 0:
if poly_list_type[0] == 'L1' or poly_list_type[0] == 'L3' or poly_list_type[0] == 'L4' or poly_list_type[0] == 'U2' or poly_list_type[0] == 'U4':
x_coaxial_cable_coordinate = (polygons[0][0,0] + polygons[0][2,0])/2
y_coaxial_cable_coordinate = (polygons[0][0,1] + polygons[0][2,1])/2
elif poly_list_type[0] == 'L2':
x_coaxial_cable_coordinate = (polygons[0][5,0] + polygons[0][1,0])/2
y_coaxial_cable_coordinate = (polygons[0][5,1] + polygons[0][1,1])/2
elif poly_list_type[0] == 'U1':
x_coaxial_cable_coordinate = (polygons[0][1,0] + polygons[0][3,0])/2
y_coaxial_cable_coordinate = (polygons[0][1,1] + polygons[0][3,1])/2
elif poly_list_type[0] == 'U3':
x_coaxial_cable_coordinate = (polygons[0][7,0] + polygons[0][1,0])/2
y_coaxial_cable_coordinate = (polygons[0][7,1] + polygons[0][1,1])/2
'''
#### check wheather the feed point is in range of patch.
polygon_boundary = hp.getBoundary(polygons) # get the boundary of the patch.
try:
range_edges = hp.get2_suitable_edges_for_coaxial_cable(polygon_boundary,(centroidX_substrate,centroidY_substrate))
except:
pass
#print(x_coaxial_cable_coordinate)
#print(range_edges[1][1][1])
# fix the coaxial point.
if range_edges != []:
if len(range_edges) == 2:
if (x_coaxial_cable_coordinate > range_edges[1][1][0]):
# NOTE: this needs to revise because it does not include all of the case.
#print(outFile)
#print('__________')
#x_coaxial_cable_coordinate = x_coaxial_cable_coordinate - (x_coaxial_cable_coordinate - range_edges[1][1][1]) - 2
x_coaxial_cable_coordinate = (range_edges[1][1][0] - range_edges[0][1][0])/2
else:
if (x_coaxial_cable_coordinate > range_edges[-1][1][0]) or (x_coaxial_cable_coordinate > range_edges[-3][1][0] and x_coaxial_cable_coordinate < range_edges[-2][1][0]):
x_coaxial_cable_coordinate = (range_edges[-1][1][0] - range_edges[-2][1][0])/2
'''
# open a temporary script file.
# tmpScriptFile = 'tempPatch.vbs'
fid = open(tmpScriptFile, 'w')
# create a new HFSS project.
hfss.hfssNewProject(fid)
hfss.hfssInsertDesign(fid, 'NxN_uStrip_Patch')
# Create substrate.
hfss.hfssBox(fid, 'Substrate', [startX , startY , 0], [length_W, length_L, -Substrate[2]], 'mm')
hfss.hfssAssignMaterial(fid,'Substrate',anten.substrate_material)
name_all_polys = []
for i in range(len(polygons)):
# draw each polygon.
hfss.hfssPolyline1(fid,'polygon'+str(i+1),polygons[i],'mm')
name_all_polys.append('polygon' + str(i+1))
if len(name_all_polys) != 1:
hfss.hfssUnite(fid,name_all_polys)
hfss.hfssRename(fid,'polygon1','patch')
hfss.hfssAssignPE(fid, 'Perf1', ['patch'], False)
# draw a ground plane.
hfss.hfssRectangle(fid, 'GroundPlane', 'Z', [startX,startY,-Substrate[2]], Substrate[0] + addition_number, Substrate[1]\
+ addition_number, 'mm');
#hfss.hfssAssignPE(fid, 'GND', ['GroundPlane']);
# get the suitable coordinate of the coaxial cable.
# draw the coaxial cable.
hfss.hfssCircle(fid, 'Groundcir', 'Z', [x_coaxial_cable_coordinate, y_coaxial_cable_coordinate, -Substrate[2]], 1, 'mm')
hfss.hfssSubtract(fid,['GroundPlane'],['Groundcir'])
hfss.hfssAssignPE(fid, 'GND', ['GroundPlane'],False);
hfss.hfssCylinder(fid, 'Cyl1', 'Z', [x_coaxial_cable_coordinate, y_coaxial_cable_coordinate,\
-Substrate[2]], 0.3, Substrate[2], 'mm')
hfss.hfssAssignMaterial(fid,'Cyl1','copper')
hfss.hfssCoaxialCable(fid, ['Cyl1_In', 'Cyl1_Er','Cyl1_Out'], 'Z', [x_coaxial_cable_coordinate, y_coaxial_cable_coordinate,\
-Substrate[2]-5], [0.3, 0.7, 1], 5, 'mm')
hfss.hfssAssignMaterial(fid,'Cyl1_In','copper')
hfss.hfssAssignMaterial(fid,'Cyl1_Er','air')
hfss.hfssAssignMaterial(fid,'Cyl1_Out','copper')
# feed.
hfss.hfssCircle(fid,'feed','Z',[x_coaxial_cable_coordinate, y_coaxial_cable_coordinate, -Substrate[2]-5],0.7,'mm')
hfss.hfssAssignLumpedPort(fid, 'Port1','feed', [x_coaxial_cable_coordinate, y_coaxial_cable_coordinate+0.7,\
-Substrate[2]-5], [x_coaxial_cable_coordinate, y_coaxial_cable_coordinate+0.3, -Substrate[2]-5], 'mm')
# draw radiation boundaries.
hfss.hfssBox(fid, 'AirBox', [startX - Lambda/4, startY - Lambda/4, -5 - Lambda/2 - Substrate[2]], [length_W + Lambda/2,\
length_L + Lambda/2, AirZ], 'mm');
hfss.hfssAssignRadiation(fid, 'ABC', 'AirBox');
hfss.hfssSetTransparency(fid, ['AirBox'], 0.95);
############################ insert solution.
hfss.hfssInsertSolution(fid, 'Solution1', fC/1e9)
hfss.hfssInterpolatingSweep(fid, 'Sweep1', 'Solution1',fStart, fStop, npoints)
# Create return loss report (new HFSS-API)
hfss.hfssCreateReport1(fid,'ReturnLoss',1,1,'Solution1',\
['Freq'],['Freq','db(S(Port1,Port1))'],'Sweep1','NULL','Sweep')
# Save the project to a temporary file and solve it.
#hfss.hfssSolveSetup(fid, 'Solution1');
#Export the S11 report to .tab file
# solve.
hfss.hfssSolveSetup(fid, 'Solution1')
#hfss.hfssSaveProject(fid, hfssFile, anten.hfss_save);
hfss.hfssExportToFile(fid, 'ReturnLoss', outFile, 'tab')
fid.close()
import GP_prog as gpg import Helper as hp import initGlobal as init initGP = init.GP() a = gpg.makeGP_prog(initGP.maxSub, initGP.maxPat, initGP.maxBlue, True) hp.drawtree(a) #hp.drawNodeIDs(a) #a.childs[1].valueofnode.plot() hp.UpdateNodeIDs(a, 0) nodes = hp.nodelist() xxx = hp.CreateNodeLists(a, nodes) #print(a.substrate_size) print(xxx.redlist) print(xxx.type_of_each_red) #print(xxx.subbluelist) #print(xxx.bluelist) #print(xxx.substratelist) #print(xxx.gensublist) #print(xxx.genpatlist) hp.drawNodeIDs(a)
def insert_chrom(or_tree, chromosome, subtree_chrom_, IDlist):
# insert_chrom function is used to insert the red nodes into suitable tree.
# tree: is the tree need be inserted after the red nodes extracted.
# chromosome: is the list that saves all extracted values of red nodes.
# subtree_chrom: is the list that save all extracted red nodes.
# IDlist: is the list that save all ID of the extracted node.
# Note: The tree is used as the input of this function need be deepcopy before.
import initGlobal as init
Sub = init.Sub()
if init.Re_trainning:
import update_state as us
AnT = init.AnT()
#Sub = init.Sub()
L = init.L()
U = init.U()
low = init.lowlevel()
GP = init.GP()
#path = us.load_temporary_path()
us.update_all_saved_parameters(AnT, Sub, L, U, GP, low)
tree = copy.deepcopy(or_tree)
subtree_chrom = copy.deepcopy(subtree_chrom_)
#drawtree(tree)
length = len(chromosome)
for i in range(length):
subtree_chrom[i].valueofnode = chromosome[
i] # insert all values into subtree_chrom before insert to GP_tree(tree).
for i in range(len(chromosome)):
tree = replaceSubtree(tree, subtree_chrom[i], IDlist[i])
#drawNodeIDs(tree)
## update tree (substrate layer).
UpdateNodeIDs(tree, 0)
#drawtree(tree)
tree.childs[0].childs[0].valueofnode = []
for i in range(len(tree.childs[0].childs[0].childs)
): # resave the sizes of substrate layer into addsub3 node.
tree.childs[0].childs[0].valueofnode.append(
tree.childs[0].childs[0].childs[i].valueofnode)
temp = tree.childs[0].childs[
0].valueofnode # save the sizes of substrate layer into TEMP variable.
tree.childs[0].valueofnode = []
for i in range(3):
# calculate all of the real substrate's parameters.
if i == 0:
temp2 = round(((temp[i] + 1) / 2) *
(Sub.rangeOx[1] - Sub.rangeOx[0]) + Sub.rangeOx[0],
4) # Ox edge
elif i == 1:
temp2 = round(((temp[i] + 1) / 2) *
(Sub.rangeOy[1] - Sub.rangeOy[0]) + Sub.rangeOy[0],
4) # Oy edge.
else:
temp2 = round(((temp[i] + 1) / 2) *
(Sub.rangeOz[1] - Sub.rangeOz[0]) + Sub.rangeOz[0],
4) # Oz edge.
tree.childs[0].valueofnode.append(temp2)
# Secondly create patterns.
MaxX = tree.childs[0].valueofnode[
0] - Sub.decrease ### real MaxX,Y are decreased 1mm before to create
# any pattern unit(like L1,U1,U2,...).
MaxY = tree.childs[0].valueofnode[1] - Sub.decrease
Zsize = tree.childs[0].valueofnode[2]
tree.substrate_size = [MaxX + Sub.decrease, MaxY + Sub.decrease, Zsize]
MaxXY = [MaxX - Sub.decrease, MaxY - Sub.decrease]
ResetSynthesischeck(tree.childs[1].childs[0].childs[0],
tree.childs[1].childs[0].childs[0].nodeID)
tree.childs[1].childs[0].childs[0] = gp.updateFullBlueTree(
tree.childs[1].childs[0].childs[0], MaxXY, 4)
tree.childs[1].childs[0].valueofnode = gp.get_val_frombluetree(
copy.deepcopy(tree.childs[1].childs[0].childs[0]))
tree.childs[1].valueofnode = tree.childs[1].childs[0].valueofnode
del subtree_chrom
del temp
del temp2
return tree