# Network X , which depth searching option to select for this use?

I am trying to ensure a global correct orientation of my normals. I.e make sure they point outwards everywhere.

This is my method:

1. I have a coordinate list `x y c n` . At each point in coordinate list I create edges from the point to its 5 nearest neighbours.
2. I Weight each edge with (`1-n1.n2`).
3. Compute a minimal spanning tree.
4. Traverse this tree in depth first order.
5. Start traversing at the point with the greatest `z` value, force the normal of this point to be orientated towards the positive `z` axis.
6. Assign orientation to subsequent points that are consistent with their preceeding point, for example if current point `p1` has orientation `n1`, and next point visited is `p2`, if `n1.n2<0` then `n2` is replaced by `-n2`.

I am not sure how to do the depth first traversing and implement steps 5,6. My code is below.

Many thanks!

``````import numpy as np
from sklearn.neighbors import NearestNeighbors

import networkx as nx

#Get coordinates
f_name = 'Bunnylarge'
coord = np.genfromtxt(str(f_name)+'.txt',autostrip=True)

#Fit nearest neighbours to coordinates
neigh = NearestNeighbors(5)
neigh.fit(coord[:,:3])

#Get the point with highest z value , this will be used as the starting point for my depth search
z_max_point = np.where(coord[:,2]==np.max(coord[:,2]))
z_max_point=int(z_max_point[0])

#Create a graph
G = nx.Graph()

#Add all points and there neighbours to graph, make the weight equal to the distance between points
for i in range(0,len(coord)):

d = neigh.kneighbors(coord[i,:3])

k = 5
for c in range(1,k):
p1 = d[1][0][0]
p2 = d[1][0][c]
n1 = coord[d[1][0][0],3:6]
n2 = coord[d[1][0][c],3:6]
dot = np.dot(n1,n2)

G.add_edge(p1,p2,weight =1-dot)

#Get minimum spanning tree of graph
#M = nx.minimum_spanning_edges(G,weight = 'weight',data=True)
M = nx.minimum_spanning_edges(G)
edgelist = list(M)

#Convert minimum spanning tree into graph to be able to depth searched
D = nx.from_edgelist(edgelist)

if coord[z_max_point,5] < 0 : #ie normal doesnt point out
coord[z_max_point,3:6]=-coord[z_max_point,3:6]

#Compute the DFS, start at the z_max_point
T = nx.dfs_tree(D,source = z_max_point)

#Go through the depth searched order and if subsequent points have for example a n1*n2<0 then make n2=-n2
#for i in list(T.edges()):
#for i in nx.dfs_successors(D,z_max_point):
n1 = coord[z_max_point,3:6]

#for i in nx.dfs_postorder_nodes(D,z_max_point):
for i in nx.dfs_tree(D,z_max_point):
print i

n2 = coord[i,3:6]

if np.dot(n1,n2)<0:
coord[i,3:6]=-coord[i,3:6]

n2 = n1
print 'done'
np.savetxt('testnormals2.xyz',coord)
``````
-