"""遺傳算法實現(xiàn)求函數(shù)極大值—Zjh"""
import numpy as np
import random
import matplotlib.pyplot as plt
class Ga():
 """求出二進制編碼的長度"""
 def __init__(self):
  self.boundsbegin = -2
  self.boundsend = 3
  precision = 0.0001 # 運算精確度
  self.Bitlength = int(np.log2((self.boundsend - self.boundsbegin)/precision))+1#%染色體長度
  self.popsize = 50# 初始種群大小
  self.Generationmax = 12# 最大進化代數(shù)
  self.pcrossover = 0.90# 交叉概率
  self.pmutation = 0.2# 變異概率
  self.population=np.random.randint(0,2,size=(self.popsize,self.Bitlength))
 
 """計算出適應(yīng)度"""
 def fitness(self,population):
  Fitvalue=[]
  cumsump = []
  for i in population:
   x=self.transform2to10(i)#二進制對應(yīng)的十進制
   xx=self.boundsbegin + x * (self.boundsend - self.boundsbegin) / (pow(2,self.Bitlength)-1)
   s=self.targetfun(xx)
   Fitvalue.append(s)
  fsum=sum(Fitvalue)
  everypopulation=[x/fsum for x in Fitvalue]
  cumsump.append(everypopulation[0])
  everypopulation.remove(everypopulation[0])
  for j in everypopulation:
   p=cumsump[-1]+j
   cumsump.append(p)
  return Fitvalue,cumsump
 """選擇兩個基因，準備交叉"""
 def select(self,cumsump):
  seln=[]
  for i in range(2):
   j = 1
   r=np.random.uniform(0,1)
   prand =[x-r for x in cumsump]
   while prand[j] < 0:
    j = j + 1
   seln.append(j)
  return seln
 """交叉"""
 def crossover(self, seln, pc):
  d=self.population[seln[1]].copy()
  f=self.population[seln[0]].copy()
  r=np.random.uniform()
  if r<pc:
   print('yes')
   c=np.random.randint(1,self.Bitlength-1)
   print(c)
   a=self.population[seln[1]][c:]
   b=self.population[seln[0]][c:]
   d[c:]=b
   f[c:]=a
   print(d)
   print(f)
   g=d
   h=f
  else:
   g=self.population[seln[1]]
   h=self.population[seln[0]]
  return g,h
 """變異操作"""
 def mutation(self,scnew,pmutation):
  r=np.random.uniform(0, 1)
  if r < pmutation:
   v=np.random.randint(0,self.Bitlength)
   scnew[v]=abs(scnew[v]-1)
  else:
   scnew=scnew
  return scnew
 
 """二進制轉(zhuǎn)換為十進制"""
 def transform2to10(self,population):
  #x=population[-1] #最后一位的值
  x=0
  #n=len(population)
  n=self.Bitlength
  p=population.copy()
  p=p.tolist()
  p.reverse()
  for j in range(n):
   x=x+p[j]*pow(2,j)
  return x #返回十進制的數(shù)
 """目標函數(shù)"""
 def targetfun(self,x):
  #y = x∗(np.sin(10∗(np.pi)∗x))+ 2
  y=x*(np.sin(10*np.pi*x))+2
  return y
 
if __name__ == '__main__':
 Generationmax=12
 gg=Ga()
 scnew=[]
 ymax=[]
 #print(gg.population)
 Fitvalue, cumsump=gg.fitness(gg.population)
 Generation = 1
 while Generation < Generationmax +1:
  Fitvalue, cumsump = gg.fitness(gg.population)
  for j in range(0,gg.popsize,2):
   seln = gg.select( cumsump) #返回選中的2個個體的序號
   scro = gg.crossover(seln, gg.pcrossover) #返回兩條染色體
   s1=gg.mutation(scro[0],gg.pmutation)
   s2=gg.mutation(scro[1],gg.pmutation)
   scnew.append(s1)
   scnew.append(s2)
  gg.population = scnew
  Fitvalue, cumsump = gg.fitness(gg.population)
  fmax=max(Fitvalue)
  d=Fitvalue.index(fmax)
  ymax.append(fmax)
  x = gg.transform2to10(gg.population[d])
  xx = gg.boundsbegin + x * (gg.boundsend - gg.boundsbegin) / (pow(2, gg.Bitlength) - 1)
  Generation = Generation + 1
 Bestpopulation = xx
 Targetmax = gg.targetfun(xx)
 print(xx)
 print(Targetmax)
 
x=np.linspace(-2,3,30)
y=x*(np.sin(10*np.pi*x))+2
plt.scatter(2.65,4.65,c='red')
plt.xlim(0,5)
plt.ylim(0,6)
plt.plot(x,y)
plt.annotate('local max', xy=(2.7,4.8), xytext=(3.6, 5.2),arrowprops=dict(facecolor='black', shrink=0.05))
plt.show()