opencv/samples/python2/fitline.py

#!/usr/bin/env python

'''
Robust line fitting.
==================

Example of using cv2.fitLine function for fitting line
to points in presence of outliers.

Usage
-----
fitline.py

Switch through different M-estimator functions and see,
how well the robust functions fit the line even
in case of ~50% of outliers.

Keys
----
SPACE - generaty random points
f     - change distance function
ESC   - exit
'''

import numpy as np
import cv2
import itertools as it
from common import draw_str


w, h = 512, 256

def toint(p):
    return tuple(map(int, p))

def sample_line(p1, p2, n, noise=0.0):
    p1 = np.float32(p1)
    t = np.random.rand(n,1)
    return p1 + (p2-p1)*t + np.random.normal(size=(n, 2))*noise

dist_func_names = it.cycle('CV_DIST_L2 CV_DIST_L1 CV_DIST_L12 CV_DIST_FAIR CV_DIST_WELSCH CV_DIST_HUBER'.split())
cur_func_name = dist_func_names.next()

def update(_=None):
    noise = cv2.getTrackbarPos('noise', 'fit line')
    n = cv2.getTrackbarPos('point n', 'fit line')
    r = cv2.getTrackbarPos('outlier %', 'fit line') / 100.0
    outn = int(n*r)

    p0, p1 = (90, 80), (w-90, h-80)
    img = np.zeros((h, w, 3), np.uint8)
    cv2.line(img, toint(p0), toint(p1), (0, 255, 0))

    if n > 0:
        line_points = sample_line(p0, p1, n-outn, noise)
        outliers = np.random.rand(outn, 2) * (w, h)
        points = np.vstack([line_points, outliers])
        for p in line_points:
            cv2.circle(img, toint(p), 2, (255, 255, 255), -1)
        for p in outliers:
            cv2.circle(img, toint(p), 2, (64, 64, 255), -1)
        func = getattr(cv2.cv, cur_func_name)
        vx, vy, cx, cy = cv2.fitLine(np.float32(points), func, 0, 0.01, 0.01)
        cv2.line(img, (int(cx-vx*w), int(cy-vy*w)), (int(cx+vx*w), int(cy+vy*w)), (0, 0, 255))

    draw_str(img, (20, 20), cur_func_name)
    cv2.imshow('fit line', img)

if __name__ == '__main__':
    print __doc__

    cv2.namedWindow('fit line')
    cv2.createTrackbar('noise', 'fit line', 3, 50, update)
    cv2.createTrackbar('point n', 'fit line', 100, 500, update)
    cv2.createTrackbar('outlier %', 'fit line', 30, 100, update)
    while True:
        update()
        ch = cv2.waitKey(0)
        if ch == ord('f'):
            cur_func_name = dist_func_names.next()
        if ch == 27:
            break
Fixed the shebang lines on the Python scripts. Also, removed the one from modules/python/src2/cv.py and cleared its executable bit, since it's not a script. 12 years ago			`#!/usr/bin/env python`
add #/usr/bin/env python to all python files 12 years ago
Normalize line endings and whitespace 12 years ago			`'''`
			`Robust line fitting.`
			`==================`

			`Example of using cv2.fitLine function for fitting line`
			`to points in presence of outliers.`

			`Usage`
			`-----`
			`fitline.py`

			`Switch through different M-estimator functions and see,`
			`how well the robust functions fit the line even`
			`in case of ~50% of outliers.`

			`Keys`
			`----`
			`SPACE - generaty random points`
			`f - change distance function`
			`ESC - exit`
			`'''`

			`import numpy as np`
			`import cv2`
			`import itertools as it`
			`from common import draw_str`


			`w, h = 512, 256`

			`def toint(p):`
			`return tuple(map(int, p))`

			`def sample_line(p1, p2, n, noise=0.0):`
			`p1 = np.float32(p1)`
			`t = np.random.rand(n,1)`
			`return p1 + (p2-p1)t + np.random.normal(size=(n, 2))noise`

			`dist_func_names = it.cycle('CV_DIST_L2 CV_DIST_L1 CV_DIST_L12 CV_DIST_FAIR CV_DIST_WELSCH CV_DIST_HUBER'.split())`
			`cur_func_name = dist_func_names.next()`

			`def update(_=None):`
			`noise = cv2.getTrackbarPos('noise', 'fit line')`
			`n = cv2.getTrackbarPos('point n', 'fit line')`
			`r = cv2.getTrackbarPos('outlier %', 'fit line') / 100.0`
			`outn = int(n*r)`

			`p0, p1 = (90, 80), (w-90, h-80)`
			`img = np.zeros((h, w, 3), np.uint8)`
			`cv2.line(img, toint(p0), toint(p1), (0, 255, 0))`

			`if n > 0:`
			`line_points = sample_line(p0, p1, n-outn, noise)`
			`outliers = np.random.rand(outn, 2) * (w, h)`
			`points = np.vstack([line_points, outliers])`
			`for p in line_points:`
			`cv2.circle(img, toint(p), 2, (255, 255, 255), -1)`
			`for p in outliers:`
			`cv2.circle(img, toint(p), 2, (64, 64, 255), -1)`
			`func = getattr(cv2.cv, cur_func_name)`
			`vx, vy, cx, cy = cv2.fitLine(np.float32(points), func, 0, 0.01, 0.01)`
			`cv2.line(img, (int(cx-vxw), int(cy-vyw)), (int(cx+vxw), int(cy+vyw)), (0, 0, 255))`

			`draw_str(img, (20, 20), cur_func_name)`
			`cv2.imshow('fit line', img)`

			`if __name__ == '__main__':`
			`print __doc__`

			`cv2.namedWindow('fit line')`
			`cv2.createTrackbar('noise', 'fit line', 3, 50, update)`
			`cv2.createTrackbar('point n', 'fit line', 100, 500, update)`
			`cv2.createTrackbar('outlier %', 'fit line', 30, 100, update)`
			`while True:`
			`update()`
			`ch = cv2.waitKey(0)`
			`if ch == ord('f'):`
			`cur_func_name = dist_func_names.next()`
			`if ch == 27:`
			`break`