Implementation of the algorithm for the Koch snowflake (#4207)

* Add files via upload Implementation of the algorithm for the Koch snowflake * added underscore to variable names * added newline and comment I fixed the sorting of the imports and I added a comment to the plot-function to explain what it does and why it doesn't use a doctest. Thank you to user mrmaxguns for suggesting these changes. * fixed accidental newline in the middle of expression * improved looping * moved "koch_snowflake.py" from "other" to "graphics" * Update koch_snowflake.py Co-authored-by: Christian Clauss <cclauss@me.com>
2024-11-23 21:11:08 +00:00 · 2021-02-20 18:39:39 +05:30 · 2021-02-20 18:39:39 +05:30 · 6bb9a027bb
commit 6bb9a027bb
parent bfb5700c67
1 changed files with 116 additions and 0 deletions
--- a/graphics/koch_snowflake.py
+++ b/graphics/koch_snowflake.py
@ -0,0 +1,116 @@
+"""
+Description
+    The Koch snowflake is a fractal curve and one of the earliest fractals to
+    have been described. The Koch snowflake can be built up iteratively, in a
+    sequence of stages. The first stage is an equilateral triangle, and each
+    successive stage is formed by adding outward bends to each side of the
+    previous stage, making smaller equilateral triangles.
+    This can be achieved through the following steps for each line:
+        1. divide the line segment into three segments of equal length.
+        2. draw an equilateral triangle that has the middle segment from step 1
+        as its base and points outward.
+        3. remove the line segment that is the base of the triangle from step 2.
+    (description adapted from https://en.wikipedia.org/wiki/Koch_snowflake )
+    (for a more detailed explanation and an implementation in the
+    Processing language, see  https://natureofcode.com/book/chapter-8-fractals/
+    #84-the-koch-curve-and-the-arraylist-technique )
+
+Requirements (pip):
+    - matplotlib
+    - numpy
+"""
+
+
+from __future__ import annotations
+
+import matplotlib.pyplot as plt  # type: ignore
+import numpy
+
+# initial triangle of Koch snowflake
+VECTOR_1 = numpy.array([0, 0])
+VECTOR_2 = numpy.array([0.5, 0.8660254])
+VECTOR_3 = numpy.array([1, 0])
+INITIAL_VECTORS = [VECTOR_1, VECTOR_2, VECTOR_3, VECTOR_1]
+
+# uncomment for simple Koch curve instead of Koch snowflake
+# INITIAL_VECTORS = [VECTOR_1, VECTOR_3]
+
+
+def iterate(initial_vectors: list[numpy.ndarray], steps: int) -> list[numpy.ndarray]:
+    """
+    Go through the number of iterations determined by the argument "steps".
+    Be careful with high values (above 5) since the time to calculate increases
+    exponentially.
+    >>> iterate([numpy.array([0, 0]), numpy.array([1, 0])], 1)
+    [array([0, 0]), array([0.33333333, 0.        ]), array([0.5       , \
+0.28867513]), array([0.66666667, 0.        ]), array([1, 0])]
+    """
+    vectors = initial_vectors
+    for i in range(steps):
+        vectors = iteration_step(vectors)
+    return vectors
+
+
+def iteration_step(vectors: list[numpy.ndarray]) -> list[numpy.ndarray]:
+    """
+    Loops through each pair of adjacent vectors. Each line between two adjacent
+    vectors is divided into 4 segments by adding 3 additional vectors in-between
+    the original two vectors. The vector in the middle is constructed through a
+    60 degree rotation so it is bent outwards.
+    >>> iteration_step([numpy.array([0, 0]), numpy.array([1, 0])])
+    [array([0, 0]), array([0.33333333, 0.        ]), array([0.5       , \
+0.28867513]), array([0.66666667, 0.        ]), array([1, 0])]
+    """
+    new_vectors = []
+    for i, start_vector in enumerate(vectors[:-1]):
+        end_vector = vectors[i + 1]
+        new_vectors.append(start_vector)
+        difference_vector = end_vector - start_vector
+        new_vectors.append(start_vector + difference_vector / 3)
+        new_vectors.append(
+            start_vector + difference_vector / 3 + rotate(difference_vector / 3, 60)
+        )
+        new_vectors.append(start_vector + difference_vector * 2 / 3)
+    new_vectors.append(vectors[-1])
+    return new_vectors
+
+
+def rotate(vector: numpy.ndarray, angle_in_degrees: float) -> numpy.ndarray:
+    """
+    Standard rotation of a 2D vector with a rotation matrix
+    (see https://en.wikipedia.org/wiki/Rotation_matrix )
+    >>> rotate(numpy.array([1, 0]), 60)
+    array([0.5      , 0.8660254])
+    >>> rotate(numpy.array([1, 0]), 90)
+    array([6.123234e-17, 1.000000e+00])
+    """
+    theta = numpy.radians(angle_in_degrees)
+    c, s = numpy.cos(theta), numpy.sin(theta)
+    rotation_matrix = numpy.array(((c, -s), (s, c)))
+    return numpy.dot(rotation_matrix, vector)
+
+
+def plot(vectors: list[numpy.ndarray]) -> None:
+    """
+    Utility function to plot the vectors using matplotlib.pyplot
+    No doctest was implemented since this function does not have a return value
+    """
+    # avoid stretched display of graph
+    axes = plt.gca()
+    axes.set_aspect("equal")
+
+    # matplotlib.pyplot.plot takes a list of all x-coordinates and a list of all
+    # y-coordinates as inputs, which are constructed from the vector-list using
+    # zip()
+    x_coordinates, y_coordinates = zip(*vectors)
+    plt.plot(x_coordinates, y_coordinates)
+    plt.show()
+
+
+if __name__ == "__main__":
+    import doctest
+
+    doctest.testmod()
+
+    processed_vectors = iterate(INITIAL_VECTORS, 5)
+    plot(processed_vectors)