I am trying to generate an image of a random contour using python but I couldn't find an easy way to do it.

Here is an example sort of what I want:

enter image description here

Initially I tought of doing it using matplotlib and gaussian functions, but I could not even get close to the image I showed.

Is there a simple way to do it?

I appreciate any help

3 Answers 3


The problem is that the kind of random shapes shown in the question is not truely random. They are somehow smoothed, ordered, seemingly random shapes. While creating truely random shapes is easy with the computer, creating those pseudo-random shapes is much easier done by using a pen and paper.

One option is hence to create such shapes interactively. This is shown in the question Interactive BSpline fitting in Python .

If you want to create random shapes programmatically, we may adapt the solution to How to connect points taking into consideration position and orientation of each of them using cubic Bezier curves.

The idea is to create a set of random points via get_random_points and call a function get_bezier_curve with those. This creates a set of bezier curves which are smoothly connected to each other at the input points. We also make sure they are cyclic, i.e. that the transition between the start and end point is smooth as well.

import numpy as np
from scipy.special import binom
import matplotlib.pyplot as plt

bernstein = lambda n, k, t: binom(n,k)* t**k * (1.-t)**(n-k)

def bezier(points, num=200):
    N = len(points)
    t = np.linspace(0, 1, num=num)
    curve = np.zeros((num, 2))
    for i in range(N):
        curve += np.outer(bernstein(N - 1, i, t), points[i])
    return curve

class Segment():
    def __init__(self, p1, p2, angle1, angle2, **kw):
        self.p1 = p1; self.p2 = p2
        self.angle1 = angle1; self.angle2 = angle2
        self.numpoints = kw.get("numpoints", 100)
        r = kw.get("r", 0.3)
        d = np.sqrt(np.sum((self.p2-self.p1)**2))
        self.r = r*d
        self.p = np.zeros((4,2))
        self.p[0,:] = self.p1[:]
        self.p[3,:] = self.p2[:]

    def calc_intermediate_points(self,r):
        self.p[1,:] = self.p1 + np.array([self.r*np.cos(self.angle1),
        self.p[2,:] = self.p2 + np.array([self.r*np.cos(self.angle2+np.pi),
        self.curve = bezier(self.p,self.numpoints)

def get_curve(points, **kw):
    segments = []
    for i in range(len(points)-1):
        seg = Segment(points[i,:2], points[i+1,:2], points[i,2],points[i+1,2],**kw)
    curve = np.concatenate([s.curve for s in segments])
    return segments, curve

def ccw_sort(p):
    d = p-np.mean(p,axis=0)
    s = np.arctan2(d[:,0], d[:,1])
    return p[np.argsort(s),:]

def get_bezier_curve(a, rad=0.2, edgy=0):
    """ given an array of points *a*, create a curve through
    those points. 
    *rad* is a number between 0 and 1 to steer the distance of
          control points.
    *edgy* is a parameter which controls how "edgy" the curve is,
           edgy=0 is smoothest."""
    p = np.arctan(edgy)/np.pi+.5
    a = ccw_sort(a)
    a = np.append(a, np.atleast_2d(a[0,:]), axis=0)
    d = np.diff(a, axis=0)
    ang = np.arctan2(d[:,1],d[:,0])
    f = lambda ang : (ang>=0)*ang + (ang<0)*(ang+2*np.pi)
    ang = f(ang)
    ang1 = ang
    ang2 = np.roll(ang,1)
    ang = p*ang1 + (1-p)*ang2 + (np.abs(ang2-ang1) > np.pi )*np.pi
    ang = np.append(ang, [ang[0]])
    a = np.append(a, np.atleast_2d(ang).T, axis=1)
    s, c = get_curve(a, r=rad, method="var")
    x,y = c.T
    return x,y, a

def get_random_points(n=5, scale=0.8, mindst=None, rec=0):
    """ create n random points in the unit square, which are *mindst*
    apart, then scale them."""
    mindst = mindst or .7/n
    a = np.random.rand(n,2)
    d = np.sqrt(np.sum(np.diff(ccw_sort(a), axis=0), axis=1)**2)
    if np.all(d >= mindst) or rec>=200:
        return a*scale
        return get_random_points(n=n, scale=scale, mindst=mindst, rec=rec+1)

You may use those functions e.g. as

fig, ax = plt.subplots()

rad = 0.2
edgy = 0.05

for c in np.array([[0,0], [0,1], [1,0], [1,1]]):

    a = get_random_points(n=7, scale=1) + c
    x,y, _ = get_bezier_curve(a,rad=rad, edgy=edgy)


enter image description here

We may check how the parameters influence the result. There are essentially 3 parameters to use here:

  • rad, the radius around the points at which the control points of the bezier curve sit. This number is relative to the distance between adjacent points and should hence be between 0 and 1. The larger the radius, the sharper the features of the curve.
  • edgy, a parameter to determine the smoothness of the curve. If 0 the angle of the curve through each point will be the mean between the direction to adjacent points. The larger it gets, the more the angle will be determined only by one adjacent point. The curve hence gets "edgier".
  • n the number of random points to use. Of course the minimum number of points is 3. The more points you use, the more feature rich the shapes can become; at the risk of creating overlaps or loops in the curve.

enter image description here enter image description here enter image description here

  • 3
    Based on this excellent answer, I wrote a small project that allows to do a few things with Bezier curves (generate random shapes, generate datasets of random shapes, mesh shapes, mesh domain with shape as a hole, etc). People reading this page might be interested in it : github.com/jviquerat/bezier_shapes Dec 5, 2019 at 8:53
  • I just posted a similar question that might be of interest (hopefully not a duplicate): stackoverflow.com/questions/63107373/… Jul 27, 2020 at 11:04
  • This is a very helpful and detailed answer with well-written code, thanks! Nov 8, 2021 at 9:54

matplotlib Path

A simple way to achieve random and quite smoothed shapes is using matplotlib.path module.

Using a cubic Bézier curve, most of the lines will be smoothed, and the number of sharp edges will be one of the parameters to tune.

The steps would be the following. First the parameters of the shape are defined, these are the number of sharp edges n and the maximum perturbation with respect to the default position in the unit circle r. In this example, the points are moved from the unit circle with a radial correction, which modifies the radius from 1 to a random number between 1-r,1+r.

That is why the vertices are defined as sinus or cosinus of the corresponding angle times the radius factor, to place the dots in the circle and then modify their radius in order to introduce the random component. The stack, .T to transpose and [:,None] are merely to convert the arrays to the input accepted by matplotlib.

Below there is an example using this kind of radial correction:

import numpy as np

import matplotlib.pyplot as plt
from matplotlib.path import Path
import matplotlib.patches as patches

n = 8 # Number of possibly sharp edges
r = .7 # magnitude of the perturbation from the unit circle, 
# should be between 0 and 1
N = n*3+1 # number of points in the Path
# There is the initial point and 3 points per cubic bezier curve. Thus, the curve will only pass though n points, which will be the sharp edges, the other 2 modify the shape of the bezier curve

angles = np.linspace(0,2*np.pi,N)
codes = np.full(N,Path.CURVE4)
codes[0] = Path.MOVETO

verts = np.stack((np.cos(angles),np.sin(angles))).T*(2*r*np.random.random(N)+1-r)[:,None]
verts[-1,:] = verts[0,:] # Using this instad of Path.CLOSEPOLY avoids an innecessary straight line
path = Path(verts, codes)

fig = plt.figure()
ax = fig.add_subplot(111)
patch = patches.PathPatch(path, facecolor='none', lw=2)

ax.set_xlim(np.min(verts)*1.1, np.max(verts)*1.1)
ax.set_ylim(np.min(verts)*1.1, np.max(verts)*1.1)
ax.axis('off') # removes the axis to leave only the shape


Which for n=8 and r=0.7 produces shapes like these:


Gaussian filtered matplotlib Path

There is also the option of generating the shape with the code above for a single shape, and then use scipy to performe a gaussian filtering of the generated image.

The main idea behind performing a gaussian filter and retrieving the smoothed shape is to create a filled shape; save the image as a 2d array (whose values will be between 0 and 1 as it will be a greyscale image); then apply the gaussian filter; and eventually, get the smoothed shape as the 0.5 contour of the filtered array.

Therefore, this second version would look like:

# additional imports
from skimage import color as skolor # see the docs at scikit-image.org/
from skimage import measure
from scipy.ndimage import gaussian_filter

sigma = 7 # smoothing parameter
# ...
path = Path(verts, codes)

fig = plt.figure()
ax = fig.add_axes([0,0,1,1]) # create the subplot filling the whole figure
patch = patches.PathPatch(path, facecolor='k', lw=2) # Fill the shape in black
# ...


##### Smoothing ####
# get the image as an array of values between 0 and 1
data = np.frombuffer(fig.canvas.tostring_rgb(), dtype=np.uint8)
data = data.reshape(fig.canvas.get_width_height()[::-1] + (3,))
gray_image = skolor.rgb2gray(data)

# filter the image
smoothed_image = gaussian_filter(gray_image,sigma)

# Retrive smoothed shape as 0.5 contour
smooth_contour = measure.find_contours(smoothed_image[::-1,:], 0.5)[0] 
# Note, the values of the contour will range from 0 to smoothed_image.shape[0] 
# and likewise for the second dimension, if desired, 
# they should be rescaled to go between 0,1 afterwards

# compare smoothed ans original shape
fig = plt.figure(figsize=(8,4))
ax1 = fig.add_subplot(1,2,1)
patch = patches.PathPatch(path, facecolor='none', lw=2)
ax1.set_xlim(np.min(verts)*1.1, np.max(verts)*1.1)
ax1.set_ylim(np.min(verts)*1.1, np.max(verts)*1.1)
ax1.axis('off') # removes the axis to leave only the shape
ax2 = fig.add_subplot(1,2,2)
ax2.plot(smooth_contour[:, 1], smooth_contour[:, 0], linewidth=2, c='k')

smooth shape

  • fig = plt.figure() NameError: name 'plt' is not defined @OriolAbril
    – pippo1980
    Feb 7, 2021 at 10:13
  • import matplotlib.pyplot as plt Feb 24, 2021 at 18:48

To answer your question, there isn't a simple way to do it. Generating random things that look and feel natural is a far more difficult problem than it might seem at first - it's why things like perlin noise are techniques of importance.

Any traditional programmatic approach (not involving, say, neural networks) would probably end up as an involved multi-step process of choosing random points, placing shapes, drawing lines, etc, fine-tuned until it looks the way you want it. Getting anything that reliably generates shapes as dynamic- and organic-looking as your examples from scratch will be very tough with this sort of approach.

If you're more interested in the result than the implementation, you might try finding a library that generates convincing-looking smooth random textures and cutting contour lines out of those. That's the only 'easy' approach that comes to mind right now. Here is a perlin noise example. Note the shapes formed from gray levels.Perlin noise, quantized colors.

  • Your example has some good shapes. Is it possible to extract a single shape from this function?
    – klaus
    Jun 7, 2018 at 3:05
  • @klaus If the image can be stored as an array, then yes. One part of my answer actually consists in retrieving contour coordinates from an array.
    – OriolAbril
    Jun 8, 2018 at 20:40
  • 1
    can you give an example of the libraries?
    – Kai Wang
    Jun 14, 2018 at 16:13

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