M, at row
i and column
j, I'd like to iterate over all the neighboring values in a circular spiral.
The point of doing this is to test some function,
f, which depends on M, to find the radius away from
(i, j) in which
f looks like this:
def f(x, y): """do stuff with x and y, and return a bool"""
and would be called like this:
R = numpy.zeros(M.shape, dtype=numpy.int) # for (i, j) in M for (radius, (cx, cy)) in circle_around(i, j): if not f(M[i][j], M[cx][cy]): R[cx][cy] = radius - 1 break
circle_around is the function that returns (an iterator to) indices in a circular spiral. So for every point in
M, this code would compute and store the radius from that point in which
If there's a more efficient way of computing
R, I'd be open to that, too.
Thanks to everyone who submitted answers. I've written a short function to plot the output from your
circle_around iterators, to show what they do. If you update your answer or post a new one, you can use this code to validate your solution.
from matplotlib import pyplot as plt def plot(g, name): plt.axis([-10, 10, -10, 10]) ax = plt.gca() ax.yaxis.grid(color='gray') ax.xaxis.grid(color='gray') X, Y = ,  for i in xrange(100): (r, (x, y)) = g.next() X.append(x) Y.append(y) print "%d: radius %d" % (i, r) plt.plot(X, Y, 'r-', linewidth=2.0) plt.title(name) plt.savefig(name + ".png")
Here are the results:
plot(circle_around(0, 0), "F.J"):
plot(circle_around(0, 0, 10), "WolframH"):
I've coded up Magnesium's suggestion as follows:
def circle_around_magnesium(x, y): import math theta = 0 dtheta = math.pi / 32.0 a, b = (0, 1) # are there better params to use here? spiral = lambda theta : a + b*theta lastX, lastY = (x, y) while True: r = spiral(theta) X = r * math.cos(theta) Y = r * math.sin(theta) if round(X) != lastX or round(Y) != lastY: lastX, lastY = round(X), round(Y) yield (r, (lastX, lastY)) theta += dtheta
plot(circle_around(0, 0, 10), "magnesium"):
As you can see, none of the results that satisfy the interface I'm looking for have produced a circular spiral that covers all of the indices around 0, 0. F.J's is the closest, although WolframH's hits the right points, just not in spiral order.