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714 lines
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Python

"""
5 years ago
import pickle
self.NUM_LABELS = args['label'].shape[1]
self.init_logs(**args)
def init_logs(self,**args):
self.log_dir = args['logs'] if 'logs' in args else 'logs'
self.mkdir(self.log_dir)
#
#
for key in ['train','output'] :
self.mkdir(os.sep.join([self.log_dir,key]))
self.mkdir (os.sep.join([self.log_dir,key,self.CONTEXT]))
self.train_dir = os.sep.join([self.log_dir,'train',self.CONTEXT])
self.out_dir = os.sep.join([self.log_dir,'output',self.CONTEXT])
if self.logger :
#
# We will clear the logs from the data-store
#
column = self.ATTRIBUTES['synthetic']
db = self.logger.db
if db[column].count() > 0 :
db.backup.insert({'name':column,'logs':list(db[column].find()) })
db[column].drop()
def load_meta(self,column):
"""
This function is designed to accomodate the uses of the sub-classes outside of a strict dependency model.
Because prediction and training can happen independently
"""
# suffix = "-".join(column) if isinstance(column,list)else column
suffix = self.get.suffix()
_name = os.sep.join([self.out_dir,'meta-'+suffix+'.json'])
if os.path.exists(_name) :
attr = json.loads((open(_name)).read())
for key in attr :
value = attr[key]
setattr(self,key,value)
self.train_dir = os.sep.join([self.log_dir,'train',self.CONTEXT])
self.out_dir = os.sep.join([self.log_dir,'output',self.CONTEXT])
def log_meta(self,**args) :
_object = {
# '_id':'meta',
'CONTEXT':self.CONTEXT,
'ATTRIBUTES':self.ATTRIBUTES,
'BATCHSIZE_PER_GPU':self.BATCHSIZE_PER_GPU,
'Z_DIM':self.Z_DIM,
"X_SPACE_SIZE":self.X_SPACE_SIZE,
"D_STRUCTURE":self.D_STRUCTURE,
"G_STRUCTURE":self.G_STRUCTURE,
"NUM_GPUS":self.NUM_GPUS,
"NUM_LABELS":self.NUM_LABELS,
"MAX_EPOCHS":self.MAX_EPOCHS,
"ROW_COUNT":self.ROW_COUNT
}
if args and 'key' in args and 'value' in args :
key = args['key']
value= args['value']
object[key] = value
# suffix = "-".join(self.column) if isinstance(self.column,list) else self.column
suffix = self.get.suffix()
_name = os.sep.join([self.out_dir,'meta-'+suffix])
f = open(_name+'.json','w')
f.write(json.dumps(_object))
return _object
def mkdir (self,path):
if not os.path.exists(path) :
os.mkdir(os.sep.join(root))
def load_meta(self, column):
super().load_meta(column)
self.discriminator.load_meta(column)
def network(self,**args) :
"""
This function will build the network that will generate the synthetic candidates
:inputs matrix of data that we need
:dim dimensions of ...
"""
x = args['inputs']
tmp_dim = self.Z_DIM if 'dim' not in args else args['dim']
label = args['label']
def __init__(self,**args):
y_hat = self.network(inputs=x_hat, label=label)
grad = tf.gradients(y_hat, [x_hat])[0]
slopes = tf.sqrt(tf.reduce_sum(tf.square(grad), 1))
gradient_penalty = tf.reduce_mean((slopes - 1.) ** 2)
#all_regs = tf.get_collection(tf.GraphKeys.REGULARIZATION_LOSSES)
all_regs = tf.compat.v1.get_collection(tf.compat.v1.GraphKeys.REGULARIZATION_LOSSES)
w_distance = -tf.reduce_mean(y_hat_real) + tf.reduce_mean(y_hat_fake)
loss = w_distance + 10 * gradient_penalty + sum(all_regs)
#tf.add_to_collection('dlosses', loss)
tf.compat.v1.add_to_collection('dlosses', loss)
return w_distance, loss
"""
features_placeholder = tf.compat.v1.placeholder(shape=self._REAL.shape, dtype=tf.float32)
init = tf.compat.v1.global_variables_initializer()
saver = tf.compat.v1.train.Saver()
df = pd.DataFrame()
CANDIDATE_COUNT = 1000
NTH_VALID_CANDIDATE = count = np.random.choice(np.arange(2,60),2)[0]
with tf.compat.v1.Session() as sess:
# sess.run(init)
saver.restore(sess, model_dir)
break
tf.compat.v1.reset_default_graph()
return df.to_dict(orient='list')
# return df.to_dict(orient='list')
# count = str(len(os.listdir(self.out_dir)))
# _name = os.sep.join([self.out_dir,self.CONTEXT+'-'+count+'.csv'])
# df.to_csv(_name,index=False)
# output.extend(np.round(f))
# for m in range(2):
# for n in range(2, self.NUM_LABELS):
# idx1 = (demo[:, m] == 1)
# idx2 = (demo[:, n] == 1)
# idx = [idx1[j] and idx2[j] for j in range(len(idx1))]
# num = np.sum(idx)
# print ("___________________list__")
# print (idx1)
# print (idx2)
# print (idx)
# print (num)
# print ("_____________________")
# nbatch = int(np.ceil(num / self.BATCHSIZE_PER_GPU))
# label_input = np.zeros((nbatch*self.BATCHSIZE_PER_GPU, self.NUM_LABELS))
# label_input[:, n] = 1
# label_input[:, m] = 1
# output = []
# for i in range(nbatch):
# f = sess.run(fake,feed_dict={y: label_input[i* self.BATCHSIZE_PER_GPU:(i+1)* self.BATCHSIZE_PER_GPU]})
# output.extend(np.round(f))
# output = np.array(output)[:num]
# print ([m,n,output])
# np.save(self.out_dir + str(m) + str(n), output)