# pythonのエラーを解決したいです．ValueError: The truth value of an array with more than one element is ambiguous. Use a.any() or a.all()

(py27) D:\Desktop\pi>python train.py FB15k/freebase_mtr100_mte100-train.txt FB15k/freebase_mtr100_mte100-valid.txt
Traceback (most recent call last):
File "train.py", line 54, in <module>
transe.fit(X,nepochs=nepochs,validationset=V)
File "D:\Desktop\pi\transe.py", line 101, in fit
if not validationset == None: print (i,self.meanrank(validationset))
ValueError: The truth value of an array with more than one element is ambiguous. Use a.any() or a.all()


import numpy as np
from sklearn.preprocessing import normalize

class TRANSE:
def __init__(self,n,m,r,k,lamb,b,d):
self.n = n # no. of entities
self.m = m # no. of relationships
self.r = r # margin
self.k = k # no. of dimensions
self.lamb = lamb # learning rate
self.b = b # size of minibatch
self.d = d # distance measure ('l1' or 'l2')

def meanrank(self,V,nsamples=1000):
ret = 0.
k = 0
for h,r,t in V:
dsim = self.predict(h,r)
ret += (dsim<dsim[t]).sum()
k += 1
if k >= nsamples: break
return ret/k

def get_batches(self,S,b):
for i in range(S.shape[0]/b-1):
yield S[i*b:(i+1)*b]
yield S[(S.shape[0]/b-1)*b:]

def negative_sampling(self,batch):
r = np.random.randint(2, size=batch.shape[0])
e = np.random.randint(self.n, size=batch.shape[0])
return np.vstack([batch.T,r,e]).T

count = {}
count['e'] = np.zeros(self.n)
count['l'] = np.zeros(self.m)

T = self.negative_sampling(batch) # unif
for h,r,t,rnd,e in T:
if rnd == 1: h2 = h; t2 = e
else: h2 = e; t2 = t
if self.f(h,r,t) + self.r - self.f(h2,r,t2) > 0:
count['e'][h] += 1
count['e'][t] += 1
count['e'][h2] += 1
count['e'][t2] += 1
count['l'][r] += 1
count['e'][count['e']==0] = 1 # avoid division by zero
count['l'][count['l']==0] = 1 # avoid division by zero

if self.d == 'l1':
return (self.params['e'][h]+self.params['l'][r]-self.params['e'][t])/np.abs(self.params['e'][h]+self.params['l'][r]-self.params['e'][t])
elif self.d == 'l2':
return (self.params['e'][h]+self.params['l'][r]-self.params['e'][t])/np.linalg.norm(self.params['e'][h]+self.params['l'][r]-self.params['e'][t])

def f(self,h,r,t):
if self.d == 'l1':
return np.abs(self.params['e'][h]+self.params['l'][r]-self.params['e'][t]).sum()
elif self.d == 'l2':
return np.linalg.norm(self.params['e'][h]+self.params['l'][r]-self.params['e'][t])

def init_params(self):
e = np.random.uniform(-6./self.k, 6./self.k, (self.n,self.k))
l = normalize(np.random.uniform(-6./self.k, 6./self.k, (self.m,self.k)))
params = {}
params['e']=e
params['l']=l
return params

def fit(self,S,nepochs=1000,validationset=None):
self.params = self.init_params()

for i in range(nepochs):
np.random.shuffle(S)
for batch in self.get_batches(S,self.b):
self.params['e'] = normalize(self.params['e'])