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I'm trying to find (but not draw!) contour lines for some data:

from pprint import pprint 
import matplotlib.pyplot 
z = [[0.350087, 0.0590954, 0.002165], [0.144522, 0.885409, 0.378515], 
     [0.027956, 0.777996, 0.602663], [0.138367, 0.182499, 0.460879], 
     [0.357434, 0.297271, 0.587715]] 
cn = matplotlib.pyplot.contour(z) 

I know cn contains the contour lines I want, but I can't seem to get to them. I've tried several things:

print dir(cn) 
print dir(cn.collections[0]) 
print dir(cn.collections[0].figure) 

to no avail. I know cn is a ContourSet, and cn.collections is an array of LineCollections. I would think a LineCollection is an array of line segments, but I can't figure out how to extract those segments.

My ultimate goal is to create a KML file that plots data on a world map, and the contours for that data as well.

However, since some of my data points are close together, and others are far away, I need the actual polygons (linestrings) that make up the contours, not just a rasterized image of the contours.

I'm somewhat surprised qhull doesn't do something like this.

Using Mathematica's ListContourPlot and then exporting as SVG works, but I want to use something open source.

I can't use the well-known CONREC algorithm because my data isn't on a mesh (there aren't always multiple y values for a given x value, and vice versa).

The solution doesn't have to python, but does have to be open source and runnable on Linux.

share|improve this question

migrated from Aug 18 '13 at 23:42

This question came from our site for users of Mathematica.

up vote 13 down vote accepted

You can get the vertices back by looping over collections and paths and using the iter_segments() method of matplotlib.path.Path.

Here's a function that returns the vertices as a set of nested lists of contour lines, contour sections and arrays of x,y vertices:

import numpy as np

def get_contour_verts(cn):
    contours = []
    # for each contour line
    for cc in cn.collections:
        paths = []
        # for each separate section of the contour line
        for pp in cc.get_paths():
            xy = []
            # for each segment of that section
            for vv in pp.iter_segments():

    return contours


It's also possible to compute the contours without plotting anything using the undocumented matplotlib._cntr C module:

from matplotlib import pyplot as plt
from matplotlib import _cntr as cntr

z = np.array([[0.350087, 0.0590954, 0.002165],
              [0.144522,  0.885409, 0.378515],
              [0.027956,  0.777996, 0.602663],
              [0.138367,  0.182499, 0.460879], 
              [0.357434,  0.297271, 0.587715]])

x, y = np.mgrid[:z.shape[0], :z.shape[1]]
c = cntr.Cntr(x, y, z)

# trace a contour at z == 0.5
res = c.trace(0.5)

# result is a list of arrays of vertices and path codes
# (see docs for matplotlib.path.Path)
nseg = len(res) // 2
segments, codes = res[:nseg], res[nseg:]

fig, ax = plt.subplots(1, 1)
img = ax.imshow(z.T, origin='lower')
p = plt.Polygon(segments[0], fill=False, color='w')

enter image description here

share|improve this answer
This did the trick, thanks! (the first one that is; haven't tested the second one, but I'm sure it would work too). Curious: does the 2nd solution require an xy mesh, or would it work with arbitrary x and y values? – barrycarter Aug 19 '13 at 18:30
You would need to give it a mesh, although you could always use something like scipy.interpolate.griddata to get this – ali_m Aug 19 '13 at 19:03
Do you expect cntr.Cntr() to be faster than matplotlib.pyplot.contour() ? – Istopopoki Oct 6 '15 at 15:49
@lstopopoki That would be my naïve assumption, since _cntr would not involve any plotting overhead. If performance is a concern then you should probably time both methods. – ali_m Oct 6 '15 at 15:57
@ali_m The _cntr approach is timing about two orders of magnitude faster on my machine. Thanks for pointing out this nice undocumented functionality--how did you learn of it? – America Feb 4 at 13:59

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