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DRAW.py
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DRAW.py
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import matplotlib.pyplot as plt
import matplotlib.colors as colors
import networkx as nx
import numpy as np
from My_count import count
@count
def general_darw(nodes, celements, X, volume, t_ime, foldername, itr, r_ound, s_tep, which_one, wt, ht, u):
ss = str(general_darw.counter)
draw_number = ss.zfill(5)
size_ = (5, 9)
a0 = 0
if which_one == 1:
Draw_GROUND_dashed(nodes, celements, foldername, draw_number, size_, a0)
elif which_one == 2:
Draw_mod(nodes, celements, X, volume, t_ime, foldername, itr, r_ound, s_tep, draw_number, size_, u)
else:
Draw_mod_final(nodes, celements, X, volume, t_ime, foldername, itr, r_ound, s_tep, draw_number, size_, u)
def Draw_GROUND_dashed(nodes, elements, foldername, draw_number, size_, a0):
fig, ax = plt.subplots(figsize=size_)
G = nx.Graph()
pos = {}
node_names = {}
node_colors = []
for i in nodes.keys():
G.add_node(i)
pos.update({i: [nodes[i].x, nodes[i].y]})
node_names.update({i: nodes[i].name})
if nodes[i].tip == 1: # boundary
node_colors.append('b')
elif nodes[i].tip == 2: # load node
if nodes[i].load[1] > 0 or nodes[i].load[0] > 0:
node_colors.append('g')
x_load = nodes[i].x
y_load = nodes[i].y
else:
node_colors.append('r')
x_load = nodes[i].x
y_load = nodes[i].y
elif nodes[i].tip == 3: # added nodes
node_colors.append('lime')
else:
node_colors.append('k')
nx.draw_networkx_nodes(G, pos, node_color=node_colors, alpha=1, node_size=25, node_shape='o', linewidths=0)
for i in elements.keys():
i_pos1 = elements[i].nodei.name
i_pos2 = elements[i].nodej.name
if elements[i].inn == True: G.add_edge(i_pos1, i_pos2)
nx.draw_networkx_edges(G, pos, edge_color='lightgrey', width=1, ax=ax, style='solid')
plt.axis('off')
plt.suptitle(draw_number + ' - GS', fontsize=10)
plt.show()
png_name = draw_number
fig.savefig(str(foldername + '/' + draw_number + '.pdf'), bbox_inches='tight')
fig.savefig(str(foldername + '/' + png_name + '.png'))
def Draw_mod(nodes, celements, X, volume, t_ime, foldername, itr, r_ound, s_tep, draw_number, size_, u):
X_dic = [i for i, k in X.items() if k > 0.05]
nodeset1 = []
nodeset2 = []
for i in X_dic:
nodeset1.append(celements[float(i)].nodei.name)
nodeset2.append(celements[float(i)].nodej.name)
sts = {}
for i in X_dic:
nodes_ = [celements[float(i)].nodei.name, celements[float(i)].nodej.name]
dal = [u[j] for j in nodes_]
dal = [item for sublist in dal for item in sublist] # Displacement values for each member of Unchecked elements list
sts[i] = ((np.sqrt(((dal[3] + celements[i].nodej.x) - (dal[0] + celements[i].nodei.x)) ** 2 + ((dal[4] + celements[i].nodej.y) - (dal[1] + celements[i].nodei.y)) ** 2) - celements[i].length))/celements[i].length
node_list = list(set(nodeset1) | set(nodeset2))
## Drawing the Nodes ----------------------------
fig, ax = plt.subplots(figsize=size_)
G = nx.Graph()
pos = {}
node_names = {}
node_colors = []
for i in nodes.keys():
G.add_node(i)
pos.update({i: [nodes[i].x, nodes[i].y]})
node_names.update({i: nodes[i].name})
if nodes[i].tip == 1: # boundary
node_colors.append('b')
elif nodes[i].tip == 2: # load point
if max(nodes[i].load) > 0: node_colors.append('g')
else: node_colors.append('r')
elif nodes[i].tip == 3: # added nodes
node_colors.append('lime')
else:
if i in node_list: node_colors.append('k')
else: node_colors.append('lightgrey')
nx.draw_networkx_nodes(G, pos, node_color=node_colors, alpha=1, node_size=30, node_shape='o', linewidths=0)
# nx.draw_networkx_labels(G, pos, node_names) # If you want to see the node numbers to analize the results
## Drawing the Edges ----------------------------
edge_w = {}
edge_c = {}
shum = 0
for i in celements.keys():
if i in X_dic and X[i] > 0:
shum += 1
i_pos1 = celements[i].nodei.name
i_pos2 = celements[i].nodej.name
G.add_edge(i_pos1, i_pos2)
edge_w.update({(i_pos1, i_pos2): 5 * X[i]})
if sts[i] > 0:
edge_c.update({(i_pos1, i_pos2): 'b'})
elif sts[i] < 0:
edge_c.update({(i_pos1, i_pos2): 'r'})
else:
i_pos1 = celements[i].nodei.name
i_pos2 = celements[i].nodej.name
G.add_edge(i_pos1, i_pos2)
edge_w.update({(i_pos1, i_pos2): 0})
edge_c.update({(i_pos1, i_pos2): 'lightgrey'})
edge_c = list(edge_c.values())
edge_w = list(edge_w.values())
nx.draw_networkx_edges(G, pos, edge_color=edge_c, width=edge_w, ax=ax, alpha=1)
# print('shum is:', shum)
plt.axis('off')
plt.suptitle('|ST:' + str(round(t_ime, 4)) + '|W:' + str(round(volume, 4)) + '|R:' + str(r_ound) + '|S:' + str(s_tep) + '|I:' + str(itr), fontsize=10)
plt.show()
png_name = draw_number
fig.savefig(str(foldername + '/' + png_name + '.pdf'), bbox_inches='tight')
fig.savefig(str(foldername + '/' + png_name + '.png'))
def Draw_mod_final(nodes, celements, X, volume, t_ime, foldername, itr, r_ound, s_tep, draw_number, size_, u):
X_dic = [i for i, k in X.items() if k > 0.05]
nodeset1 = []
nodeset2 = []
for i in X_dic:
nodeset1.append(celements[float(i)].nodei.name)
nodeset2.append(celements[float(i)].nodej.name)
node_list = list(set(nodeset1) | set(nodeset2))
## Drawing the Nodes ----------------------------
fig, ax = plt.subplots(figsize=size_)
G = nx.Graph()
pos = {}
node_colors = []
for i in nodes.keys():
G.add_node(i)
pos.update({i: [nodes[i].x, nodes[i].y]})
if nodes[i].tip == 1: # boundary
node_colors.append('b')
elif nodes[i].tip == 2: # load point
if max(nodes[i].load) > 0:
node_colors.append('g')
else:
node_colors.append('r')
elif nodes[i].tip == 3: # added nodes
node_colors.append('lime')
else:
if i in node_list:
node_colors.append('k')
else:
node_colors.append('lightgrey')
nx.draw_networkx_nodes(G, pos, node_color=node_colors, alpha=1, node_size=30, node_shape='o', linewidths=0)
## Drawing the Edges ----------------------------
edge_w = {}
edge_c = {}
shum = 0
for i in celements.keys():
if i in X_dic and X[i] > 0.01:
i_pos1 = celements[i].nodei.name
i_pos2 = celements[i].nodej.name
G.add_edge(i_pos1, i_pos2)
edge_w.update({(i_pos1, i_pos2): 5 * X[i]})
edge_c.update({(i_pos1, i_pos2): 'k'})
else:
i_pos1 = celements[i].nodei.name
i_pos2 = celements[i].nodej.name
G.add_edge(i_pos1, i_pos2)
edge_w.update({(i_pos1, i_pos2): 0})
edge_c.update({(i_pos1, i_pos2): 'lightgrey'})
edge_c = list(edge_c.values())
edge_w = list(edge_w.values())
nx.draw_networkx_edges(G, pos, edge_color=edge_c, width=edge_w, ax=ax, alpha=1)
# print('shum is:', shum)
plt.axis('off')
# plt.suptitle('|ST:' + str(round(t_ime, 4)) + '|W:' + str(round(volume, 4)) + '|R:' + str(r_ound) + '|S:' + str(s_tep) + '|I:' + str(itr), fontsize=10)
plt.show()
png_name = 'Final'+str(u)
fig.savefig(str(foldername + '/' + png_name + '.pdf'), bbox_inches='tight')