import numpy as np

# 定義 預(yù)先設(shè)定 的閾值
STOP_THRESHOLD = 1e-4
CLUSTER_THRESHOLD = 1e-1


# 定義度量函數(shù)
def distance(a, b):
 return np.linalg.norm(np.array(a) - np.array(b))


# 定義高斯核函數(shù)
def gaussian_kernel(distance, bandwidth):
 return (1 / (bandwidth * np.sqrt(2 * np.pi))) * np.exp(-0.5 * ((distance / bandwidth)) ** 2)


# mean_shift類
class mean_shift(object):
 def __init__(self, kernel=gaussian_kernel):
  self.kernel = kernel

 def fit(self, points, kernel_bandwidth):

  shift_points = np.array(points)
  shifting = [True] * points.shape[0]

  while True:
   max_dist = 0
   for i in range(0, len(shift_points)):
    if not shifting[i]:
     continue
    p_shift_init = shift_points[i].copy()
    shift_points[i] = self._shift_point(shift_points[i], points, kernel_bandwidth)
    dist = distance(shift_points[i], p_shift_init)
    max_dist = max(max_dist, dist)
    shifting[i] = dist > STOP_THRESHOLD

   if(max_dist < STOP_THRESHOLD):
    break
  cluster_ids = self._cluster_points(shift_points.tolist())
  return shift_points, cluster_ids

 def _shift_point(self, point, points, kernel_bandwidth):
  shift_x = 0.0
  shift_y = 0.0
  scale = 0.0
  for p in points:
   dist = distance(point, p)
   weight = self.kernel(dist, kernel_bandwidth)
   shift_x += p[0] * weight
   shift_y += p[1] * weight
   scale += weight
  shift_x = shift_x / scale
  shift_y = shift_y / scale
  return [shift_x, shift_y]

 def _cluster_points(self, points):
  cluster_ids = []
  cluster_idx = 0
  cluster_centers = []

  for i, point in enumerate(points):
   if(len(cluster_ids) == 0):
    cluster_ids.append(cluster_idx)
    cluster_centers.append(point)
    cluster_idx += 1
   else:
    for center in cluster_centers:
     dist = distance(point, center)
     if(dist < CLUSTER_THRESHOLD):
      cluster_ids.append(cluster_centers.index(center))
    if(len(cluster_ids) < i + 1):
     cluster_ids.append(cluster_idx)
     cluster_centers.append(point)
     cluster_idx += 1
  return cluster_ids

# -*- coding: utf-8 -*-
"""
Created on Tue Oct 09 11:02:08 2018

@author: muli
"""

from sklearn.datasets.samples_generator import make_blobs
import matplotlib.pyplot as plt 
import random
import numpy as np
import MeanShift


def colors(n):
 ret = []
 for i in range(n):
 ret.append((random.uniform(0, 1), random.uniform(0, 1), random.uniform(0, 1)))
 return ret

def main():
 centers = [[-1, -1], [-1, 1], [1, -1], [1, 1]]
 X, _ = make_blobs(n_samples=300, centers=centers, cluster_std=0.4)

 mean_shifter = MeanShift.mean_shift()
 _, mean_shift_result = mean_shifter.fit(X, kernel_bandwidth=0.5)

 np.set_printoptions(precision=3)
 print('input: {}'.format(X))
 print('assined clusters: {}'.format(mean_shift_result))
 color = colors(np.unique(mean_shift_result).size)

 for i in range(len(mean_shift_result)):
  plt.scatter(X[i, 0], X[i, 1], color = color[mean_shift_result[i]])
 plt.show()


if __name__ == '__main__':
 main()