I'm trying to figure out how to animate my `networkx`

graphs using `matplotlib 2.0`

and the `animation`

module inside of it. I saw Using NetworkX with matplotlib.ArtistAnimation and Animate graph diffusion with NetworkX but I can't figure out how these update functions work even with the pseudocode.

I'm trying to step through a sequence of letters (nodes) and then plot the path from the origin `"O"`

to the current step. It will make more sense looking at the plots below. I don't want to have to render them out to make an `.mp4`

outside of `Python 3.6`

. I think it would be a good resource for people to understand how these update functions operate and how they can be applied to visualizing networks.

**How can I use an update function to animate my networkx graph below?**

Obviously the animation wouldn't be on a `matplotlib figure`

with different `ax`

objects but this is just to illustrate how the frames would be laid out.

```
import networkx as nx
import numpy as np
import matplotlib.pyplot as plt
import seaborn as sns
import matplotlib.animation as animation
def update_func(num, data, line):
# https://matplotlib.org/2.0.0/examples/animation/basic_example.html
line.set_data(data[..., :num])
return line
# Create Graph
np.random.seed(2)
G = nx.cubical_graph()
G = nx.relabel_nodes(G, {0:"O", 1:"X", 2:"XZ", 3:"Z", 4:"Y", 5:"YZ", 6: "XYZ", 7:"XY"})
pos = nx.spring_layout(G)
# Sequence of letters
sequence_of_letters = "".join(['X', 'Y', 'Z', 'Y', 'Y', 'Z']) #np.random.RandomState(0).choice(list("XYZ"), size=6, replace=True)
idx_colors = sns.cubehelix_palette(5, start=.5, rot=-.75)[::-1]
idx_weights = [3,2,1]
# General graph structure
with plt.style.context("seaborn-white"):
fig, ax = plt.subplots()
nx.draw(G, pos=pos, with_labels=True, ax=ax)
print(ax.get_xlim(), ax.get_ylim())
# (-0.10500000000000001, 1.105) (-0.088398066788676247, 0.93028441715702148)
# Build plot
with plt.style.context("seaborn-white"):
fig, axes = plt.subplots(ncols=3, nrows=2, figsize=(10,5))
for i in range(0, len(sequence_of_letters), 3):
triad = sequence_of_letters[i:i+3]
for j in range(1,4):
# Axes index for rows and cols
idx = i + j - 1
row_idx, col_idx = {True: (0,idx), False: (1,idx - 3)}[idx < 3]
ax = axes[row_idx][col_idx]
# Path in Graph
path = ["O"] + ["".join(sorted(set(triad[:k + 1]))) for k in range(j)]
# Background nodes
nx.draw_networkx_edges(G, pos=pos, ax=ax, edge_color="gray")
null_nodes = nx.draw_networkx_nodes(G, pos=pos, nodelist=set(G.nodes()) - set(path), node_color="white", ax=ax)
null_nodes.set_edgecolor("black")
# Query nodes
query_nodes = nx.draw_networkx_nodes(G, pos=pos, nodelist=path, node_color=idx_colors[:len(path)], ax=ax)
query_nodes.set_edgecolor("white")
nx.draw_networkx_labels(G, pos=pos, labels=dict(zip(path,path)), font_color="white", ax=ax)
edgelist = [path[k:k+2] for k in range(len(path) - 1)]
nx.draw_networkx_edges(G, pos=pos, edgelist=edgelist, width=idx_weights[:len(path)], ax=ax)
# Scale plot ax
ax.set_title("Frame %d: "%(idx+1) + " - ".join(path), fontweight="bold")
ax.set_xlim((-0.10500000000000001, 1.105))
ax.set_ylim((-0.088398066788676247, 0.93028441715702148))
ax.set_xticks([])
ax.set_yticks([])
```