From the `collections`

attribute of the contour collection, which is returned by the `contour`

function, you can get the paths describing each contour. The paths' `vertices`

attributes then contain the ordered vertices of the contour.

Using the vertices you can approximate the contour integral 0.5*(x*dy-y*dx), which by application of Green's theorem gives you the area of the enclosed region.

However, the contours must be **fully contained in the plot**, because otherwise the contours are broken up into multiple, not necessarily connected paths and the method breaks down.

Here's the method used to compute the area enclosed of the radius function, i.e. r = (x^2 + y^2)^0.5, for r=1.0, r=2.0, r=3.0.

```
import numpy as np
import matplotlib.pylab as plt
# Use Green's theorem to compute the area
# enclosed by the given contour.
def area(vs):
a = 0
x0,y0 = vs[0]
for [x1,y1] in vs[1:]:
dx = x1-x0
dy = y1-y0
a += 0.5*(y0*dx - x0*dy)
x0 = x1
y0 = y1
return a
# Generate some test data.
delta = 0.01
x = np.arange(-3.1, 3.1, delta)
y = np.arange(-3.1, 3.1, delta)
X, Y = np.meshgrid(x, y)
r = np.sqrt(X**2 + Y**2)
# Plot the data
levels = [1.0,2.0,3.0]
cs = plt.contour(X,Y,r,levels=levels)
plt.clabel(cs, inline=1, fontsize=10)
# Get one of the contours from the plot.
for i in range(len(levels)):
contour = cs.collections[i]
vs = contour.get_paths()[0].vertices
# Compute area enclosed by vertices.
a = area(vs)
print "r = " + str(levels[i]) + ": a =" + str(a)
plt.show()
```

Output:

```
r = 1.0: a = 2.83566351207
r = 2.0: a = 11.9922190971
r = 3.0: a = 27.3977413253
```