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- import os, sys
- import time
- import multiprocessing as mp
- import numpy as np
- import time
- from matplotlib import pyplot as plt
- from permanent import permanent
-
- def perm_ryser(a):
- ''' the permanent calculated using the ryser formula. much faster than the naive approach '''
- n,n2=a.shape
- z=np.arange(n)
- irange=xrange(2**n)
- get_index=lambda i: (i & (1 << z)) != 0
- get_term=lambda index: ((-1)**np.sum(index))*np.prod(np.sum(a[index,:], 0))
- indeces=map(get_index, irange)
- terms=map(get_term, indeces)
- return np.sum(terms)*((-1)**n)
-
- maxtime=1
- dimensions=range(1,11)
-
- for (function, label) in zip((permanent, perm_ryser), ("C", "Python")):
- counts=[]
- for dimension in dimensions:
- print dimension
- real=np.random.uniform(-1, 1, dimension*dimension).reshape((dimension, dimension))
- imag=np.random.uniform(-1, 1, dimension*dimension).reshape((dimension, dimension))
- submatrix=real+1j*imag
-
- t=time.clock()
- n=0
- while time.clock()-t < maxtime:
- for i in range(5):
- function(submatrix)
- n+=5
- counts.append(n)
-
- plt.plot(dimensions, counts, '.-', label=label)
-
- plt.ylabel('Number of permanents per second')
- plt.xlabel('Dimension')
- plt.xlim(min(dimensions), max(dimensions))
- plt.legend()
- plt.semilogy()
- plt.savefig('out.pdf')
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