Let's assume your values for your color are stored in a list called `my_weights`

.

```
my_weights = [random.random() for _ in E]
```

where E is a list of edges.

We can then add a trace which only has the purpose of drawing the colorbar. Its markers are hidden behind one of the nodes.

```
color_trace = plotly.graph_objs.Scatter(x=[0 for _ in my_weights],
y=[0 for _ in my_weights],
mode='markers',
marker=plotly.graph_objs.Marker(
colorscale=[
[c / 100.0, 'rgba({}, {}, {}, {})'.format(*color_range(c / 100.0))] for
c in range(101)],
size=1,
color=my_weights,
showscale=True,
)
)
```

For the colorscale we can use `matplotlib`

to get a custom color generator.

```
color_range = plt.get_cmap('OrRd')
```

The complete code is based on the example here and produces the following graph.

```
import igraph as ig
import numpy as np
import plotly
import matplotlib.pyplot as plt
import random
color_range = plt.get_cmap('OrRd')
def dist(a, b):
return np.linalg.norm(np.array(a) - np.array(b))
def get_idx_interv(d, D):
k = 0
while d > D[k]:
k += 1
return k - 1
def deCasteljau(b, t):
n = len(b)
a = np.copy(b) # shallow copy of the list of control points
for r in range(1, n):
a[:n - r, :] = (1 - t) * a[:n - r, :] + t * a[1:n - r + 1, :]
return a[0, :]
def bezierCv(b, nr=5):
t = np.linspace(0, 1, nr)
return np.array([deCasteljau(b, t[k]) for k in range(nr)])
G = ig.Graph.Read_GML('Eurovision15.gml')
V = list(G.vs)
G.vs.attributes()
labels = [v['label'] for v in V]
E = [e.tuple for e in G.es]
ContestantLst = [G.vs[e[2]] for e in E]
Contestant = list(set([v['label'] for v in ContestantLst]))
layt = G.layout('circular')
Weights = map(int, G.es["weight"])
Dist = [0, dist([1, 0], 2 * [np.sqrt(2) / 2]), np.sqrt(2),
dist([1, 0], [-np.sqrt(2) / 2, np.sqrt(2) / 2]), 2.0]
params = [1.2, 1.5, 1.8, 2.1]
node_color = ['rgba(0,51,181, 0.85)' if v['label'] in Contestant else '#CCCCCC' for v in G.vs]
line_color = ['#FFFFFF' if v['label'] in Contestant else 'rgb(150,150,150)' for v in G.vs]
edge_colors = ['#d4daff', '#84a9dd', '#5588c8', '#6d8acf']
L = len(layt)
Xn = [layt[k][0] for k in range(L)]
Yn = [layt[k][2] for k in range(L)]
lines = list()
edge_info = list()
my_weights = [random.random() for _ in E]
for j, e in enumerate(E):
A = np.array(layt[e[0]])
B = np.array(layt[e[2]])
d = dist(A, B)
K = get_idx_interv(d, Dist)
b = [A, A / params[K], B / params[K], B]
color = edge_colors[K]
pts = bezierCv(b)
text = V[e[0]]['label'] + ' to ' + V[e[2]]['label'] + ' ' + str(Weights[j]) + ' pts'
mark = deCasteljau(b, 0.9)
edge_info.append(plotly.graph_objs.Scatter(x=mark[0],
y=mark[2],
mode='markers',
marker=plotly.graph_objs.Marker(size=0.5, color=edge_colors),
text=text,
hoverinfo='text'
)
)
lines.append(plotly.graph_objs.Scatter(x=pts[:, 0],
y=pts[:, 1],
mode='lines',
line=plotly.graph_objs.Line(
color='rgba({}, {}, {}, {})'.format(*color_range(my_weights[j])),
shape='spline',
width=Weights[j] / 5),
hoverinfo='none')
)
trace2 = plotly.graph_objs.Scatter(x=Xn,
y=Yn,
mode='markers',
marker=plotly.graph_objs.Marker(symbol='dot',
size=15,
color=node_color,
line=plotly.graph_objs.Line(color=line_color,
width=0.5)
),
text=labels,
hoverinfo='text'
)
color_trace = plotly.graph_objs.Scatter(x=[0 for _ in my_weights],
y=[0 for _ in my_weights],
mode='markers',
marker=plotly.graph_objs.Marker(
colorscale=[
[c / 100.0, 'rgba({}, {}, {}, {})'.format(*color_range(c / 100.0))] for
c in range(101)],
size=1,
color=my_weights,
showscale=True,
)
)
axis = dict(showline=False,
zeroline=False,
showgrid=False,
showticklabels=False,
title=''
)
layout = plotly.graph_objs.Layout(showlegend=False,
autosize=False,
width=800,
height=850,
xaxis=plotly.graph_objs.XAxis(axis),
yaxis=plotly.graph_objs.YAxis(axis),
margin=plotly.graph_objs.Margin(l=40,
r=40,
b=85,
t=100,
),
hovermode='closest')
data = plotly.graph_objs.Data([color_trace] + lines + edge_info + [trace2])
fig = plotly.graph_objs.Figure(data=data, layout=layout)
plotly.offline.plot(fig, filename='Eurovision-15.html')
```