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metrics.py
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metrics.py
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from sklearn.metrics import f1_score
from sklearn.metrics import roc_auc_score
from sklearn.metrics import average_precision_score
from sklearn import metrics
from munkres import Munkres, print_matrix
import numpy as np
class linkpred_metrics():
def __init__(self, edges_pos, edges_neg):
self.edges_pos = edges_pos
self.edges_neg = edges_neg
def get_roc_score(self, emb, feas):
# if emb is None:
# feed_dict.update({placeholders['dropout']: 0})
# emb = sess.run(model.z_mean, feed_dict=feed_dict)
def sigmoid(x):
return 1 / (1 + np.exp(-x))
# Predict on test set of edges
adj_rec = np.dot(emb, emb.T)
preds = []
pos = []
for e in self.edges_pos:
preds.append(sigmoid(adj_rec[e[0], e[1]]))
pos.append(feas['adj_orig'][e[0], e[1]])
preds_neg = []
neg = []
for e in self.edges_neg:
preds_neg.append(sigmoid(adj_rec[e[0], e[1]]))
neg.append(feas['adj_orig'][e[0], e[1]])
preds_all = np.hstack([preds, preds_neg])
labels_all = np.hstack([np.ones(len(preds)), np.zeros(len(preds))])
roc_score = roc_auc_score(labels_all, preds_all)
ap_score = average_precision_score(labels_all, preds_all)
return roc_score, ap_score, emb
class clustering_metrics():
def __init__(self, true_label, predict_label):
self.true_label = true_label
self.pred_label = predict_label
def clusteringAcc(self):
# best mapping between true_label and predict label
l1 = list(set(self.true_label))
numclass1 = len(l1)
l2 = list(set(self.pred_label))
numclass2 = len(l2)
if numclass1 != numclass2:
print('Class Not equal, Error!!!!')
return 0
cost = np.zeros((numclass1, numclass2), dtype=int)
for i, c1 in enumerate(l1):
mps = [i1 for i1, e1 in enumerate(self.true_label) if e1 == c1]
for j, c2 in enumerate(l2):
mps_d = [i1 for i1 in mps if self.pred_label[i1] == c2]
cost[i][j] = len(mps_d)
# match two clustering results by Munkres algorithm
m = Munkres()
cost = cost.__neg__().tolist()
indexes = m.compute(cost)
# get the match results
new_predict = np.zeros(len(self.pred_label))
for i, c in enumerate(l1):
# correponding label in l2:
c2 = l2[indexes[i][1]]
# ai is the index with label==c2 in the pred_label list
ai = [ind for ind, elm in enumerate(self.pred_label) if elm == c2]
new_predict[ai] = c
acc = metrics.accuracy_score(self.true_label, new_predict)
f1_macro = metrics.f1_score(self.true_label, new_predict, average='macro')
precision_macro = metrics.precision_score(self.true_label, new_predict, average='macro')
recall_macro = metrics.recall_score(self.true_label, new_predict, average='macro')
f1_micro = metrics.f1_score(self.true_label, new_predict, average='micro')
precision_micro = metrics.precision_score(self.true_label, new_predict, average='micro')
recall_micro = metrics.recall_score(self.true_label, new_predict, average='micro')
return acc, f1_macro, precision_macro, recall_macro, f1_micro, precision_micro, recall_micro
def evaluationClusterModelFromLabel(self):
nmi = metrics.normalized_mutual_info_score(self.true_label, self.pred_label)
adjscore = metrics.adjusted_rand_score(self.true_label, self.pred_label)
acc, f1_macro, precision_macro, recall_macro, f1_micro, precision_micro, recall_micro = self.clusteringAcc()
print('ACC=%f, f1_macro=%f, precision_macro=%f, recall_macro=%f, f1_micro=%f, precision_micro=%f, recall_micro=%f, NMI=%f, ADJ_RAND_SCORE=%f' % (acc, f1_macro, precision_macro, recall_macro, f1_micro, precision_micro, recall_micro, nmi, adjscore))
fh = open('recoder.txt', 'a')
fh.write('ACC=%f, f1_macro=%f, precision_macro=%f, recall_macro=%f, f1_micro=%f, precision_micro=%f, recall_micro=%f, NMI=%f, ADJ_RAND_SCORE=%f' % (acc, f1_macro, precision_macro, recall_macro, f1_micro, precision_micro, recall_micro, nmi, adjscore) )
fh.write('\r\n')
fh.flush()
fh.close()
return acc, nmi, f1_macro