def main(_):
cpu = os.cpu_count()
tf_config = _tf_config(flags) #1
# 分布式需要 TF_CONFIG 环境变量
os.environ['TF_CONFIG'] = json.dumps(tf_config) #2
session_config = ConfigProto(device_count={'CPU': cpu},
inter_op_parallelism_threads=cpu // 2,
intra_op_parallelism_threads=cpu // 2,
device_filters=flags.device_filters,
allow_soft_placement=True)
strategy = experimental.ParameterServerStrategy()
run_config = estimator.RunConfig(
**{
'save_summary_steps': 100,
'save_checkpoints_steps': 1000,
'keep_checkpoint_max': 10,
'log_step_count_steps': 100,
'train_distribute': strategy,
'eval_distribute': strategy,
}).replace(session_config=session_config)
model = estimator.Estimator(
model_fn=model_fn,
model_dir='/home/axing/din/checkpoints/din', #实际应用中是分布式文件系统
config=run_config,
params={
'tf_config': tf_config,
'decay_rate': 0.9,
'decay_steps': 10000,
'learning_rate': 0.1
})
train_spec = estimator.TrainSpec(
input_fn=lambda: input_fn(mode='train',
num_workers=flags.num_workers,
worker_index=flags.worker_index,
pattern='/home/axing/din/dataset/*'), #3
max_steps=1000 #4
)
# 这里就假设验证集和训练集地址一样了,实际应用中是肯定不一样的。
eval_spec = estimator.EvalSpec(
input_fn=lambda: input_fn(mode='eval',
pattern='/home/axing/din/dataset/*'),
steps=100, # 每次验证 100 个 batch size 的数据
throttle_secs=60 # 每隔至少 60 秒验证一次
)
estimator.train_and_evaluate(model, train_spec, eval_spec)
def main(_):
cpu = os.cpu_count()
session_config = tf.ConfigProto(
device_count={'GPU': 0,
'CPU': cpu},
inter_op_parallelism_threads=cpu // 2,
intra_op_parallelism_threads=cpu // 2,
device_filters=[],
allow_soft_placement=True)
run_config = tf.estimator.RunConfig(**{
'save_summary_steps': 100,
'save_checkpoints_steps': 1000,
'keep_checkpoint_max': 10,
'log_step_count_steps': 100
}).replace(session_config=session_config)
model = tf.estimator.Estimator(
model_fn=model_fn,
model_dir='/home/axing/din/checkpoints/din',
config=run_config,
params={
'decay_rate': 0.9,
'decay_steps': 10000,
'learning_rate': 0.1
}
)
train_spec = tf.estimator.TrainSpec(
input_fn=lambda: input_fn(mode='train', pattern='/home/axing/din/dataset/*'))
# 这里就假设验证集和训练集地址一样了,实际应用中是肯定不一样的。
eval_spec = tf.estimator.EvalSpec(
input_fn=lambda: input_fn(mode='eval', pattern='/home/axing/din/dataset/*'),
steps=100, # 每次验证 100 个 batch size 的数据
throttle_secs=60 # 每隔至少 60 秒验证一次
)
tf.estimator.train_and_evaluate(model, train_spec, eval_spec)
def peek_classification(estimator, test_df):
predict_df = test_df[150:200].copy()
pred_iter = estimator.predict(lambda: input_fn(
predict_df, num_epochs=1, shuffle=False, batch_size=10))
classes = np.array(['outside', 'tram'])
pred_class_id = []
for pred_dict in pred_iter:
pred_class_id.append(pred_dict['class_ids'])
predict_df['predicted_class'] = classes[np.array(pred_class_id)]
predict_df['correct'] = (
predict_df['predicted_class'] == 'tram') == predict_df['imInTram']
print(predict_df[['imInTram', 'predicted_class', 'correct']])
def build_model(filename):
wide_columns, deep_columns = build_model_columns()
features, labels = input_fn(filename).make_one_shot_iterator().get_next()
cols_to_vars = {}
linear_logits = tf.feature_column.linear_model(
features=features,
feature_columns=wide_columns,
cols_to_vars=cols_to_vars)
predictions = tf.reshape(tf.nn.sigmoid(linear_logits), (-1, ))
loss = tf.reduce_mean(
tf.losses.log_loss(labels=labels, predictions=predictions))
global_step = tf.train.get_or_create_global_step()
optimizer = tf.train.FtrlOptimizer(learning_rate=0.1,
l1_regularization_strength=0.1,
l2_regularization_strength=0.1)
train_op = optimizer.minimize(loss, global_step=global_step)
tf.summary.scalar('prediction/mean', tf.reduce_mean(predictions))
tf.summary.histogram('prediction', predictions)
tf.summary.scalar('metrics/loss', loss)
summary = tf.summary.merge_all()
global_vars = tf.global_variables()
uninitialized = tf.report_uninitialized_variables(tf.global_variables())
global_init = tf.global_variables_initializer()
local_init = [tf.local_variables_initializer(), tf.tables_initializer()]
return {
'train': {
'train_op': train_op,
'loss': loss,
},
'init': {
'global': global_init,
'local': local_init
},
'global_variables': global_vars,
'uninitialized': uninitialized,
'cols_to_vars': cols_to_vars,
'summary': summary,
'global_step': global_step,
}
def main():
# build graph
features, labels = input_fn(data_file='census_data/adult.data'
).make_one_shot_iterator().get_next()
model = build_model(features=features, labels=labels, mode='train')
# inspect graph variables
for col, var in model['cols_to_vars'].items():
print('Column: ', col)
print('Variable:', var)
print('-' * 50)
# create session
with tf.Session() as sess:
sess.run(model['init'])
for step in range(1, 1000):
result = sess.run(model['train'])
print('step =', step, 'loss =', result['loss'])
signature_def_map = {}
receiver = input_receiver()
receiver_tensors = receiver.receiver_tensors
pred_model = build_model(features=receiver.features, mode='predict')
output = tf.estimator.export.PredictOutput(
outputs=pred_model['predictions'])
signature_def_map['serving_default'] = output.as_signature_def(
receiver_tensors)
# print('sig def map:', signature_def_map)
local_init_op = tf.group(
tf.local_variables_initializer(),
tf.tables_initializer(),
)
builder = tf.saved_model.builder.SavedModelBuilder('export/wdl_single')
builder.add_meta_graph_and_variables(
sess, [tf.saved_model.tag_constants.SERVING],
signature_def_map=signature_def_map,
assets_collection=tf.get_collection(tf.GraphKeys.ASSET_FILEPATHS),
legacy_init_op=local_init_op,
strip_default_attrs=False)
builder.save(as_text=False)
DEFINES.model_hidden_size,
'ffn_hidden_size':
DEFINES.ffn_hidden_size,
'attention_head_size':
DEFINES.attention_head_size,
'learning_rate':
DEFINES.learning_rate,
'vocabulary_length':
vocabulary_length,
'layer_size':
DEFINES.layer_size,
'max_sequence_length':
DEFINES.max_sequence_length
})
# 학습
tf.logging.set_verbosity(tf.logging.INFO)
classifier.train(input_fn=lambda: data.
input_fn(train_input_enc, train_input_dec, train_target_dec,
DEFINES.batch_size, DEFINES.train_repeats),
steps=1000)
# 평가
print("#### 평가 ####")
eval_result = classifier.evaluate(input_fn=lambda: data.input_fn(
eval_input_enc, eval_input_dec, eval_target_dec, DEFINES.batch_size,
DEFINES.train_repeats),
steps=1)
print('\nEVAL set accuracy: {accuracy:0.3f}\n'.format(**eval_result))
tf.logging.set_verbosity(tf.logging.INFO)
estimator = tf.estimator.Estimator(
model_fn=model.model_fn,
model_dir="./model",
params={"learning_rate": 1e-4})
datasets = [
"dataset/SponzaDay8.tfrecord"
]
train = True
if train:
for i in range(NUM_EPOCHS):
print("Starting epoch", i)
estimator.train(input_fn=lambda: data.input_fn(datasets, True, 1))
# obj = estimator.predict(
# input_fn=lambda: data.input_fn1("KitchenEveningEval.tfrecord", 0))
# for p in obj:
# rgb = np.zeros((1024, 1024, 3), 'uint8')
# rgb[..., 0] = np.clip(
# np.power(1.5 * p["orig"][:, :, 0], 1.0 / 2.2) * 255, 0, 255)
# rgb[..., 1] = np.clip(
# np.power(1.5 * p["orig"][:, :, 1], 1.0 / 2.2) * 255, 0, 255)
# rgb[..., 2] = np.clip(
# np.power(1.5 * p["orig"][:, :, 2], 1.0 / 2.2) * 255, 0, 255)
# im = Image.fromarray(rgb, "RGB")
# im.show()
adagrad_optimizer = tf.train.ProximalAdagradOptimizer(
learning_rate=proxAdagrad_LEARNING_RATE, l1_regularization_strength=0.001)
tested_nums = []
accuracies = []
precisions = []
recalls = []
for learning_rate in [x * 0.01 for x in [1]]:
print(f"testing: {learning_rate}")
test_hidden_units = [15, 100]
estimator = tf.estimator.DNNClassifier(
feature_columns=[ax, ay, az, gx, gy, gz],
hidden_units=test_hidden_units,
optimizer=adam_optimizer)
estimator.train(input_fn=lambda: input_fn(
train_df, num_epochs=EPOCHS_NUM, shuffle=False, batch_size=64),
steps=None)
result = estimator.evaluate(
lambda: input_fn(test_df, num_epochs=1, shuffle=False, batch_size=64))
tested_nums.append(learning_rate)
accuracies.append(result["accuracy"])
precisions.append(result["precision"])
recalls.append(result["recall"])
print(f"A: {result['accuracy']}, B: {result['precision']}")
estimator.export_savedmodel(
export_dir_base='adam-dnn',
serving_input_receiver_fn=serving_input_receiver_fn)
pl.show_multiple_series([accuracies, precisions, recalls])
# pprint_result(result)
# peek_classification(estimator, test_df)
# model_dir="./model",
# params={"learning_rate": 1e-4,
# "class_weights": [1.0 for i in range(100)]})
#
# for i in range(15):
# estimator.train(input_fn=lambda: data.input_fn("wiki_crop", True, 1))
# ev = estimator.evaluate(input_fn=lambda: data.input_fn("eval", False, 1))
# print("Accuracy on test set: ", ev["accuracy"])
#
# res = estimator.predict(input_fn=lambda: data.input_fn("test", False, 1))
# for r in res:
# print(r["age"])
train = True
if train:
features, labels = data.input_fn("wiki_crop", True, None)
else:
features, labels = data.input_fn("test", False, 1)
input = keras.layers.Input(tensor=features)
base_model = keras.applications.InceptionV3(weights='imagenet', include_top=False, input_tensor=input)
for layer in base_model.layers:
layer.trainable = False
pooling = keras.layers.GlobalAveragePooling2D()(base_model.output)
fully_connected = keras.layers.Dense(1024, activation='relu')(pooling)
output = keras.layers.Dense(100, activation='softmax')(fully_connected)
model = keras.models.Model(input, output)
model.compile(
optimizer=keras.optimizers.SGD(1e-4),
loss='categorical_crossentropy',
target_tensors=[labels],
# 채팅 시작
for i in range(10):
question = input("Q: ")
if question == 'quit':
break
predic_input_enc = data.data_processing([question], word2idx,
DEFINES.enc_input)
predic_output_dec = data.data_processing([""], word2idx, DEFINES.dec_input)
predic_target_dec = data.data_processing([""], word2idx,
DEFINES.dec_target)
predictions = classifier.predict(input_fn=lambda: data.input_fn(
predic_input_enc, predic_output_dec, predic_target_dec, 1, 1
)) #for문을 돌때마다 네트워크 빌드& 체크포인트 적용, 작업을 수행한다->속도저하
# Estimator의 특성->보완이 필요한 부분
# 답변 문장에 대한 softmax 확률을 받는다.
prob = np.array([v['indexs'] for v in predictions])
prob = np.squeeze(prob)
# 확률적으로 답변 문장의 인덱스를 생성한다.
words_index = [pred_indices(p, beta=DEFINES.softmax_beta) for p in prob]
# 답변 문장의 인덱스를 실제 문장으로 변환한다.
answer = ""
for word in words_index:
if word != 0 and word != 2: # PAD = 0, END = 2
answer += idx2word[word]
# 채팅 시작
for i in range(100):
question = input("Q: ")
if question == 'quit':
break
predic_input_enc = data.data_processing([question], word2idx,
DEFINES.enc_input)
predic_output_dec = data.data_processing([""], word2idx, DEFINES.dec_input)
predic_target_dec = data.data_processing([""], word2idx,
DEFINES.dec_target)
# 매 번 모델을 리빌드하고 checkpoint를 reload하기 때문에 속도가 늦음.
# Estimator의 특징이므로 다른 방법으로 보완이 필요함.
predictions = classifier.predict(input_fn=lambda: data.input_fn(
predic_input_enc, predic_output_dec, predic_target_dec, 1, 1))
# 답변 문장에 대한 softmax 확률을 받는다.
prob = np.array([v['indexs'] for v in predictions])
prob = np.squeeze(prob)
# 확률적으로 답변 문장의 인덱스를 생성한다.
words_index = [pred_indices(p, beta=DEFINES.softmax_beta) for p in prob]
# 답변 문장의 인덱스를 실제 문장으로 변환한다.
answer = ""
for word in words_index:
if word != 0 and word != 2: # PAD = 0, END = 2
answer += idx2word[word]
answer += " "
def train_per_eval(session_config):
with tf.Session(config = session_config) as sess:
batch_inputs = data.input_fn(mode = "train")
model = Model(mode = "train", inputs = batch_inputs)
print ("Training Graph Loaded")
global_step = 0
saver = tf.train.Saver(max_to_keep = Hp.max_to_keep)
init = tf.global_variables_initializer()
sess.run(init)
summary_writer = tf.summary.FileWriter(Hp.logdir, graph=sess.graph)
if Hp.train_from_restore:
latest_model = tf.train.latest_checkpoint(os.path.join(Hp.logdir, "models"))
if Hp.restore_model is not None and Hp.restore_model != latest_model:
print ("Restore Model from Specific Model")
restore_model = Hp.restore_model
else:
print ("Restore Model from Last Checkpoint")
restore_model = latest_model
saver.restore(sess, restore_model)
while global_step % Hp.train_step_per_eval != 0 or global_step==0:
out = sess.run([
model.train_op,
model.global_step,
model.alignments,
model.mag_hat,
model.merged_labels,
mode.merged])
global_step = out[1]
summary = out[-1]
summary_writer.add_summary(summary, global_step)
if global_step%Hp.save_model_step == 0 and global_step!=0:
print ("Saving Model Weights during Training")
save_model_dir = os.path.join(Hp.logdir, "models")
if not os.path.exists(save_model_dir):
os.mkdir(save_model_dir)
saver.save(sess, os.path.join(save_model_dir, "model"), global_step = global_step)
# set Hp.restore_model path
#Hp.restore_model = os.path.join(save_model_dir, "model.ckpt-"+str(global_step))
Hp.train_from_restore = True
print ("saving Sample during Training")
# store a sample to listen to both on tensorboard and local files
save_sample_dir = os.path.join(Hp.logdir, "train")
if not os.path.exists(save_sample_dir):
os.mkdir(save_sample_dir)
wav_hat = signal_process.spectrogrom2wav(out[3][0])
ground_truth = signal_process.spectrogrom2wav(out[4][0])
signal_process.plot_alignment(out[2][0], gs = global_step, mode = "save_fig", path = save_sample_dir)
write(os.path.join(save_sample_dir, 'gt_{}.wav'.format(global_step)), Hp.sample_rate, ground_truth)
write(os.path.join(save_sample_dir, 'hat_{}.wav'.format(global_step)), Hp.sample_rate, wav_hat)
merged = sess.run(tf.summary.merge(
[tf.summary.audio("train/sample_gt"+str(global_step), tf.expand_dims(ground_truth, 0), Hp.sample_rate),
tf.summary.audio("train/sample_hat_gs"+str(global_step), tf.expand_dims(wav_hat, 0), Hp.sample_rate),
tf.summary.image("train/attention_gs"+str(global_step), signal_process.plot_alignment(out[2][0], gs=global_step, mode="with_return"))]))
summary_writer.add_summary(merged, global_step)
type=float,
default=0.001,
help="The learning rate for training.")
params = parser.parse_args()
run_config = tf.estimator.RunConfig(
model_dir=params.logdir,
save_checkpoints_steps=1000,
)
estimator = tf.estimator.Estimator(model_fn=model.model_fn,
config=run_config,
params=params)
tf.logging.set_verbosity('INFO')
estimator.train(
input_fn=lambda: data.input_fn(
eval=False, use_validation_set=False, params=params),
max_steps=100000,
saving_listeners=[
EvalCheckpointSaverListener(
estimator, lambda: data.input_fn(
eval=True, use_validation_set=True, params=params),
"validation"),
EvalCheckpointSaverListener(
estimator, lambda: data.input_fn(
eval=True, use_validation_set=False, params=params), "train"),
],
)
)
tested_nums = []
accuracies=[]
precisions=[]
recalls=[]
for learning_rate in [x * 0.001 for x in [1]]:
print(f"testing: {learning_rate}")
test_hidden_units = ok_hidden_units
estimator = tf.estimator.DNNClassifier(
feature_columns=[ax, ay, az, gx, gy, gz],
hidden_units=test_hidden_units,
optimizer=adadelta_optimizer
)
estimator.train(input_fn=lambda:input_fn(train_df, num_epochs=EPOCHS_NUM, shuffle=False, batch_size=64), steps=None)
result = estimator.evaluate(lambda:input_fn(test_df, num_epochs=1, shuffle=False, batch_size=64))
tested_nums.append(learning_rate)
accuracies.append(result["accuracy"])
precisions.append(result["precision"])
recalls.append(result["recall"])
print(f"A: {result['accuracy']}, B: {result['precision']}")
estimator.export_savedmodel(export_dir_base='adam-dnn', serving_input_receiver_fn=serving_input_receiver_fn)
pl.show_multiple_series([accuracies, precisions, recalls])
pprint_result(result)
peek_classification(estimator, test_df)
def main(args):
#tf.config.experimental_run_functions_eagerly(False)
print('Start training')
creds = {}
with open(args.credentails) as json_file:
creds = json.load(json_file)
if not creds:
print('Failed to load credentials file {}. Exiting'.format(args.credentails))
s3def = creds['s3'][0]
s3 = s3store(s3def['address'],
s3def['access key'],
s3def['secret key'],
tls=s3def['tls'],
cert_verify=s3def['cert_verify'],
cert_path=s3def['cert_path']
)
trainingset = '{}/{}/'.format(s3def['sets']['trainingset']['prefix'] , args.trainingset)
print('Load training set {}/{} to {}'.format(s3def['sets']['trainingset']['bucket'],trainingset,args.trainingset_dir ))
s3.Mirror(s3def['sets']['trainingset']['bucket'], trainingset, args.trainingset_dir)
trainingsetDescriptionFile = '{}/description.json'.format(args.trainingset_dir)
trainingsetDescription = json.load(open(trainingsetDescriptionFile))
training_percent = 0.8
config = {
'descripiton': args.description,
'traningset': trainingset,
'trainingset description': trainingsetDescription,
# 'dataset':args.dataset,
'batch_size': args.batch_size,
'classScale': 0.001, # scale value for each product class
'augment_rotation' : 15., # Rotation in degrees
'augment_flip_x': False,
'augment_flip_y': True,
'augment_brightness':0.,
'augment_contrast': 0.,
'augment_shift_x': 0.1, # in fraction of image
'augment_shift_y': 0.1, # in fraction of image
'scale_min': 0.5, # in fraction of image
'scale_max': 2.0, # in fraction of image
'input_shape': [args.size_y, args.size_x, args.depth],
'shape': (args.size_y, args.size_x, args.depth),
'split': tfds.Split.TRAIN,
'classes': trainingsetDescription['classes']['classes'],
'learning_rate': args.learning_rate,
'init_weights':None,
'clean': args.clean,
'epochs':args.epochs,
'training_percent':training_percent,
'training':'train[:{}%]'.format(int(100*training_percent)),
'validation':'train[{}%:]'.format(int(100*training_percent)),
'channel_order': args.channel_order,
#'training':'train[:80%]',
#'validation':'train[80%:]',
's3_address':s3def['address'],
's3_sets':s3def['sets'],
'initialmodel':args.initialmodel,
'training_dir': args.training_dir,
}
if args.initialmodel is None or len(args.initialmodel) == 0:
config['initialmodel'] = None
if args.training_dir is None or len(args.training_dir) == 0:
config['training_dir'] = tempfile.TemporaryDirectory(prefix='train', dir='.')
if args.clean:
shutil.rmtree(config['training_dir'], ignore_errors=True)
strategy = None
if(args.strategy == 'mirrored'):
strategy = tf.distribute.MirroredStrategy(devices=args.devices)
else:
device = "/gpu:0"
if args.devices is not None and len(args.devices > 0):
device = args.devices[0]
strategy = tf.distribute.OneDeviceStrategy(device=device)
print('{} distribute with {} GPUs'.format(args.strategy,strategy.num_replicas_in_sync))
savedmodelpath = '{}/{}'.format(args.savedmodel, args.savedmodelname)
if not os.path.exists(savedmodelpath):
os.makedirs(savedmodelpath)
if not os.path.exists(config['training_dir']):
os.makedirs(config['training_dir'])
with strategy.scope():
save_callback = tf.keras.callbacks.ModelCheckpoint(filepath=args.model_dir, monitor='loss',verbose=0,save_weights_only=False,save_freq='epoch')
tensorboard_callback = tf.keras.callbacks.TensorBoard(log_dir=args.model_dir, histogram_freq='epoch')
callbacks = [
#save_callback,
#tensorboard_callback
]
#train_dataset, datasetdata = input_fn(config, split=config['training'])
#val_dataset, _ = input_fn(config, split=config['validation'])
train_dataset = input_fn('train', args.trainingset_dir, config)
val_dataset = input_fn('val', args.trainingset_dir, config)
#for images, labels in train_dataset.take(1):
# for i in range(images.shape[0]):
# print(labels[i].numpy())
# config['classes'] = datasetdata.features['label'].num_classes
#train_images = int(datasetdata.splits.total_num_examples*config['training_percent'])
#val_images = int(datasetdata.splits.total_num_examples*(1.0-config['training_percent']))
train_images = config['batch_size'] # Guess training set if not provided
val_images = config['batch_size']
for dataset in trainingsetDescription['sets']:
if(dataset['name']=="train"):
train_images = dataset["length"]
if(dataset['name']=="val"):
val_images = dataset["length"]
steps_per_epoch=int(train_images/config['batch_size'])
validation_steps=int(val_images/config['batch_size'])
if(args.min):
steps_per_epoch= min(args.min_steps, steps_per_epoch)
validation_steps=min(args.min_steps, validation_steps)
config['epochs'] = 1
model = LoadModel(config, s3, args.model_dir)
# Display model
model.summary()
print("Fit model to data")
model_history = model.fit(train_dataset,
validation_data=val_dataset,
epochs=config['epochs'],
steps_per_epoch=steps_per_epoch,
validation_steps=validation_steps,
callbacks=callbacks)
history = model_history.history
if 'loss' in history:
loss = model_history.history['loss']
else:
loss = []
if 'val_loss' in history:
val_loss = model_history.history['val_loss']
else:
val_loss = []
model_description = {'config':config,
'results': history
}
#epochs = config['epochs']
graph_history(loss,val_loss,savedmodelpath)
print("Create saved model")
model.save(savedmodelpath, save_format='tf')
if args.saveonnx:
onnx_req = "python -m tf2onnx.convert --saved-model {0} --opset 10 --output {0}/model.onnx".format(savedmodelpath)
os.system(onnx_req)
print("Compute results")
PrepareInference(dataset=train_dataset, model=model)
CreatePredictions(dataset=train_dataset, model=model, config=config, outpath=savedmodelpath, imgname='train')
CreatePredictions(dataset=val_dataset, model=model, config=config, outpath=savedmodelpath, imgname='val')
print("Save results")
model_description = {'config':config,
'results': history
}
WriteDictJson(model_description, '{}/description.json'.format(savedmodelpath))
# Save confusion matrix: https://www.kaggle.com/grfiv4/plot-a-confusion-matrix
saved_name = '{}/{}'.format(s3def['sets']['model']['prefix'] , args.savedmodelname)
print('Save model to {}/{}'.format(s3def['sets']['model']['bucket'],saved_name))
if s3.PutDir(s3def['sets']['model']['bucket'], savedmodelpath, saved_name):
shutil.rmtree(savedmodelpath, ignore_errors=True)
if args.clean or args.training_dir is None or len(args.training_dir) == 0:
shutil.rmtree(config['training_dir'], ignore_errors=True)
def eval(session_config):
with tf.Session(config=session_config) as sess:
batch_inputs = data.input_fn(mode="eval")
model = Model(mode="eval", inputs=batch_inputs)
print("Evaluation Graph Loaded")
saver = tf.train.Saver(max_to_keep=Hp.max_to_keep)
init = tf.global_variables_initializer()
sess.run(init)
summary_writer = tf.summary.FileWriter(Hp.logdir, graph=sess.graph)
latest_model = tf.train.latest_checkpoint(
os.path.join(Hp.logdir, "models"))
global_step = int(latest_model.split('-')[1])
saver.restore(sess, latest_model)
print("Restore Model from Last Checkpoint")
rounds = Hp.eval_sample_num // Hp.eval_batch_size
loss = []
mag_hat = []
mag_gt = []
mel_hat = []
mel_gt = []
align = []
for i in range(rounds):
out = sess.run([
model.loss, model.mag_hat, model.merged_labels, model.mel_hat,
model.inputs_reference, model.alignments
])
loss.append(out[0])
mag_hat.extend(out[1])
mag_gt.extend(out[2])
mel_hat.extend(out[3])
mel_gt.extend(np.concatenate(out[4], axis=0))
align.extend(out[5])
print("saving Sample during Evaluation")
# store a sample to listen to both on tensorboard and local files
save_sample_dir = os.path.join(Hp.logdir, "eval")
if not os.path.exists(save_sample_dir):
os.mkdir(save_sample_dir)
with open(os.path.join(save_sample_dir, "loss"), 'a+') as fout:
fout.write("Step:{}\tLoss:{}\n".format(global_step,
np.mean(np.array(loss))))
wav_hat = signal_process.spectrogrom2wav(mag_hat[0])
ground_truth = signal_process.spectrogrom2wav(mag_gt[0])
signal_process.plot_alignment(align[0],
gs=global_step,
mode="save_fig",
path=save_sample_dir)
write(os.path.join(save_sample_dir, 'gt_{}.wav'.format(global_step)),
Hp.sample_rate, ground_truth)
write(os.path.join(save_sample_dir, 'hat_{}.wav'.format(global_step)),
Hp.sample_rate, wav_hat)
merged = sess.run(
tf.summary.merge([
tf.summary.audio("eval/sample_gt" + str(global_step),
tf.expand_dims(ground_truth, 0),
Hp.sample_rate),
tf.summary.audio("eval/sample_hat_gs" + str(global_step),
tf.expand_dims(wav_hat, 0), Hp.sample_rate),
tf.summary.image(
"eval/attention_gs" + str(global_step),
signal_process.plot_alignment(out[2][0],
gs=global_step,
mode="with_return"))
]))
summary_writer.add_summary(merged, global_step)