本文整理汇总了Python中utils.get_data方法的典型用法代码示例。如果您正苦于以下问题:Python utils.get_data方法的具体用法?Python utils.get_data怎么用?Python utils.get_data使用的例子?那么, 这里精选的方法代码示例或许可以为您提供帮助。您也可以进一步了解该方法所在类utils
的用法示例。
在下文中一共展示了utils.get_data方法的11个代码示例,这些例子默认根据受欢迎程度排序。您可以为喜欢或者感觉有用的代码点赞,您的评价将有助于系统推荐出更棒的Python代码示例。
示例1: infer
# 需要导入模块: import utils [as 别名]
# 或者: from utils import get_data [as 别名]
def infer(data_filepath='data/flowers.hdf5', z_dim=128, out_dir='gan',
n_steps=10):
G = load_model(out_dir)
val_data = get_data(data_filepath, 'train')
val_data = next(iterate_minibatches(val_data, 2))
emb_source, emb_target = val_data[1]
txts = val_data[2]
z = np.random.uniform(-1, 1, size=(1, z_dim))
G.trainable = False
for i in range(n_steps+1):
p = i/float(n_steps)
emb = emb_source * (1-p) + emb_target * p
emb = emb[None, :]
fake_image = G.predict([z, emb])[0]
img = ((fake_image + 1)*0.5)
plt.imsave("{}/fake_text_interpolation_i{}".format(out_dir, i), img)
print(i, str(txts[int(round(p))]).strip(),
file=open("{}/fake_text_interpolation.txt".format(out_dir), "a"))
开发者ID:PacktPublishing,项目名称:Hands-On-Generative-Adversarial-Networks-with-Keras,代码行数:23,代码来源:interpolation_in_text.py
示例2: infer
# 需要导入模块: import utils [as 别名]
# 或者: from utils import get_data [as 别名]
def infer(data_filepath='data/flowers.hdf5', z_dim=128, out_dir='gan',
n_samples=5):
G = load_model(out_dir)
val_data = get_data(data_filepath, 'train')
val_data = next(iterate_minibatches(val_data, n_samples))
emb, txts = val_data[1], val_data[2]
# sample z vector for inference
z = np.random.uniform(-1, 1, size=(n_samples, z_dim))
G.trainable = False
fake_images = G.predict([z, emb])
for i in range(n_samples):
img = ((fake_images[i] + 1)*0.5)
plt.imsave("{}/fake_{}".format(out_dir, i), img)
print(i, str(txts[i]).strip(),
file=open("{}/fake_text.txt".format(out_dir), "a"))
开发者ID:PacktPublishing,项目名称:Hands-On-Generative-Adversarial-Networks-with-Keras,代码行数:20,代码来源:inference.py
示例3: embedding_nearest_neighbour
# 需要导入模块: import utils [as 别名]
# 或者: from utils import get_data [as 别名]
def embedding_nearest_neighbour(n_neighbors=FLAGS.n_neighbours, num_classes=FLAGS.way, num_shots=FLAGS.shot, num_tasks=FLAGS.num_tasks,
num_encoding_dims=FLAGS.num_encoding_dims, test_set=FLAGS.test_set,
dataset=FLAGS.dataset):
print('{}-way {}-shot embedding nearest neighbour'.format(num_classes, num_shots))
if dataset != 'celeba':
_, _, _, X_test, Y_test, Z_test = get_data(dataset, num_encoding_dims, test_set)
task_generator = TaskGenerator(num_classes=num_classes, num_train_samples_per_class=num_shots, num_samples_per_class=num_shots+5)
partition = task_generator.get_partition_from_labels(Y_test)
partitions = [partition]
else:
_, _, _, X_test, attributes_test, Z_test = get_data(dataset, num_encoding_dims, test_set)
task_generator = TaskGenerator(num_classes=num_classes, num_train_samples_per_class=num_shots, num_samples_per_class=num_shots+5)
partitions = task_generator.get_celeba_task_pool(attributes_test)
tasks = task_generator.get_tasks(num_tasks=num_tasks, partitions=partitions)
accuracies = []
for i_task, task in enumerate(tasks):
if (i_task + 1) % (num_tasks // 10) == 0:
print('test {}, accuracy {:.5}'.format(i_task + 1, np.mean(accuracies)))
ind_train_few, Y_train_few, ind_test_few, Y_test_few = task
Z_train_few, Z_test_few = Z_test[ind_train_few], Z_test[ind_test_few]
knn = KNeighborsClassifier(n_neighbors=n_neighbors, n_jobs=-1)
knn.fit(Z_train_few, Y_train_few)
accuracy = knn.score(Z_test_few, Y_test_few)
accuracies.append(accuracy)
print('{}-way {}-shot embedding nearest neighbour: {:.5} with 95% CI {:.5} over {} tests'.format(num_classes, num_shots, np.mean(accuracies), 1.96*np.std(accuracies)/np.sqrt(num_tasks), num_tasks))
示例4: embedding_logistic_regression
# 需要导入模块: import utils [as 别名]
# 或者: from utils import get_data [as 别名]
def embedding_logistic_regression(C=FLAGS.inverse_reg, penalty='l2', multi_class='multinomial', num_classes=FLAGS.way, num_shots=FLAGS.shot, num_tasks=FLAGS.num_tasks,
num_encoding_dims=FLAGS.num_encoding_dims, test_set=FLAGS.test_set,
dataset=FLAGS.dataset):
print('{}-way {}-shot logistic regression'.format(num_classes, num_shots))
if dataset != 'celeba':
_, _, _, X_test, Y_test, Z_test = get_data(dataset, num_encoding_dims, test_set)
task_generator = TaskGenerator(num_classes=num_classes, num_train_samples_per_class=num_shots, num_samples_per_class=num_shots+5)
partition = task_generator.get_partition_from_labels(Y_test)
partitions = [partition]
else:
_, _, _, X_test, attributes_test, Z_test = get_data(dataset, num_encoding_dims, test_set)
task_generator = TaskGenerator(num_classes=num_classes, num_train_samples_per_class=num_shots, num_samples_per_class=num_shots+5)
partitions = task_generator.get_celeba_task_pool(attributes_test)
tasks = task_generator.get_tasks(num_tasks=num_tasks, partitions=partitions)
train_accuracies, test_accuracies = [], []
start = time.time()
for i_task, task in enumerate(tasks):
if (i_task + 1) % (num_tasks // 10) == 0:
print('test {}, train accuracy {:.5}, test accuracy {:.5}'.format(i_task + 1, np.mean(train_accuracies), np.mean(test_accuracies)))
ind_train_few, Y_train_few, ind_test_few, Y_test_few = task
Z_train_few, Z_test_few = Z_test[ind_train_few], Z_test[ind_test_few]
logistic_regression = LogisticRegression(n_jobs=-1, penalty=penalty, C=C, multi_class=multi_class, solver='saga', max_iter=1000)
logistic_regression.fit(Z_train_few, Y_train_few)
test_accuracies.append(logistic_regression.score(Z_test_few, Y_test_few))
train_accuracies.append(logistic_regression.score(Z_train_few, Y_train_few))
print('penalty={}, C={}, multi_class={}'.format(penalty, C, multi_class))
print('{}-way {}-shot logistic regression: {:.5} with 95% CI {:.5} over {} tests'.format(num_classes, num_shots, np.mean(test_accuracies), 1.96*np.std(test_accuracies)/np.sqrt(num_tasks), num_tasks))
print('Mean training accuracy: {:.5}; standard deviation: {:.5}'.format(np.mean(train_accuracies), np.std(train_accuracies)))
print('{} few-shot classification tasks: {:.5} seconds.'.format(num_tasks, time.time() - start))
示例5: cbow
# 需要导入模块: import utils [as 别名]
# 或者: from utils import get_data [as 别名]
def cbow():
params = {
'model': Philo2Vec.CBOW,
'loss_fct': Philo2Vec.NCE,
'context_window': 5,
}
x_train = get_data()
validation_words = ['kant', 'descartes', 'human', 'natural']
x_validation = [StemmingLookup.stem(w) for w in validation_words]
vb = VocabBuilder(x_train, min_frequency=5)
pv = Philo2Vec(vb, **params)
pv.fit(epochs=30, validation_data=x_validation)
return pv
示例6: skip_gram
# 需要导入模块: import utils [as 别名]
# 或者: from utils import get_data [as 别名]
def skip_gram():
params = {
'model': Philo2Vec.SKIP_GRAM,
'loss_fct': Philo2Vec.SOFTMAX,
'context_window': 2,
'num_skips': 4,
'neg_sample_size': 2,
}
x_train = get_data()
validation_words = ['kant', 'descartes', 'human', 'natural']
x_validation = [StemmingLookup.stem(w) for w in validation_words]
vb = VocabBuilder(x_train, min_frequency=5)
pv = Philo2Vec(vb, **params)
pv.fit(epochs=30, validation_data=x_validation)
return pv
示例7: get_candles
# 需要导入模块: import utils [as 别名]
# 或者: from utils import get_data [as 别名]
def get_candles(symbol, start_date, end_date, timeframe='1m', limit=1000):
"""
Return symbol candles between two dates.
https://docs.bitfinex.com/v2/reference#rest-public-candles
"""
# timestamps need to include milliseconds
start_date = start_date.int_timestamp * 1000
end_date = end_date.int_timestamp * 1000
url = f'{API_URL}/candles/trade:{timeframe}:t{symbol.upper()}/hist' \
f'?start={start_date}&end={end_date}&limit={limit}'
data = get_data(url)
return data
示例8: embedding_cluster_matching
# 需要导入模块: import utils [as 别名]
# 或者: from utils import get_data [as 别名]
def embedding_cluster_matching(num_classes=FLAGS.way, num_shots=FLAGS.shot, num_tasks=FLAGS.num_tasks,
num_clusters=FLAGS.num_clusters, num_encoding_dims=FLAGS.num_encoding_dims,
dataset=FLAGS.dataset, test_set=FLAGS.test_set):
if dataset != 'celeba':
_, _, Z_train, X_test, Y_test, Z_test = get_data(dataset, num_encoding_dims, test_set)
else:
_, _, Z_train, X_test, attributes_test, Z_test = get_data(dataset, num_encoding_dims, test_set)
start = time.time()
kmeans = KMeans(n_clusters=num_clusters, init='k-means++', random_state=0, precompute_distances=True, n_jobs=10, n_init=10, max_iter=3000).fit(Z_train)
print("Ran KMeans with n_clusters={} in {:.5} seconds, objective {}.".format(num_clusters, time.time() - start, kmeans.score(Z_train)))
if dataset != 'celeba':
task_generator = TaskGenerator(num_classes=num_classes, num_train_samples_per_class=num_shots, num_samples_per_class=num_shots+5)
partition = task_generator.get_partition_from_labels(Y_test)
partitions = [partition]
else:
task_generator = TaskGenerator(num_classes=num_classes, num_train_samples_per_class=num_shots, num_samples_per_class=num_shots+5)
partitions = task_generator.get_celeba_task_pool(attributes_test)
tasks = task_generator.get_tasks(num_tasks=num_tasks, partitions=partitions)
for num_shots in [FLAGS.shot]:
accuracies = []
start = time.time()
num_degenerate_tasks = 0
for i_task, task in enumerate(tasks):
if (i_task + 1) % (num_tasks // 10) == 0:
print('test {}, accuracy {:.5}'.format(i_task + 1, np.mean(accuracies)))
ind_train_few, Y_train_few, ind_test_few, Y_test_few = task
Z_train_few, Z_test_few = Z_test[ind_train_few], Z_test[ind_test_few]
clusters_to_labels_few = defaultdict(list)
examples_to_clusters_few = kmeans.predict(Z_train_few)
for i in range(len(Y_train_few)):
clusters_to_labels_few[examples_to_clusters_few[i]].append(Y_train_few[i])
for (cluster, labels) in list(clusters_to_labels_few.items()):
uniques, counts = np.unique(labels, return_counts=True)
clusters_to_labels_few[cluster] = [uniques[np.argmax(counts)]]
# if len(np.unique(labels)) > 1: # delete degenerate clusters
# del clusters_to_labels_few[cluster]
if len(clusters_to_labels_few) == 0:
num_degenerate_tasks += 1
continue
centroid_ind_to_cluster = np.array(list(clusters_to_labels_few.keys()))
centroids = kmeans.cluster_centers_[centroid_ind_to_cluster]
distances = distance.cdist(Z_test_few, centroids)
predicted_clusters = centroid_ind_to_cluster[np.argmin(distances, axis=1)]
predictions = []
for cluster in predicted_clusters:
predictions.append(clusters_to_labels_few[cluster][0])
accuracies.append(accuracy_score(Y_test_few, predictions))
print('dataset={}, encoder={}, num_encoding_dims={}, num_clusters={}'.format(dataset, FLAGS.encoder, num_clusters, num_encoding_dims))
print('{}-way {}-shot nearest-cluster after clustering embeddings: {:.5} with 95% CI {:.5} over {} tests'.format(num_classes, num_shots, np.mean(accuracies), 1.96*np.std(accuracies)/np.sqrt(num_tasks), num_tasks))
print('{} few-shot classification tasks: {:.5} seconds with {} degenerate tasks.'.format(num_tasks, time.time() - start, num_degenerate_tasks))
示例9: embedding_mlp
# 需要导入模块: import utils [as 别名]
# 或者: from utils import get_data [as 别名]
def embedding_mlp(num_classes=FLAGS.way, num_shots=FLAGS.shot, num_tasks=FLAGS.num_tasks,
num_encoding_dims=FLAGS.num_encoding_dims, test_set=FLAGS.test_set, dataset=FLAGS.dataset,
units=FLAGS.units, dropout=FLAGS.dropout):
import keras
from keras.layers import Dense, Dropout
from keras.losses import categorical_crossentropy
from keras.callbacks import EarlyStopping
from keras import backend as K
if dataset != 'celeba':
_, _, _, X_test, Y_test, Z_test = get_data(dataset, num_encoding_dims, test_set)
task_generator = TaskGenerator(num_classes=num_classes, num_train_samples_per_class=num_shots, num_samples_per_class=num_shots+5)
partition = task_generator.get_partition_from_labels(Y_test)
partitions = [partition]
else:
_, _, _, X_test, attributes_test, Z_test = get_data(dataset, num_encoding_dims, test_set)
task_generator = TaskGenerator(num_classes=num_classes, num_train_samples_per_class=num_shots, num_samples_per_class=num_shots+5)
partitions = task_generator.get_celeba_task_pool(attributes_test)
tasks = task_generator.get_tasks(num_tasks=num_tasks, partitions=partitions)
train_accuracies, test_accuracies = [], []
start = time.time()
for i_task, task in enumerate(tqdm(tasks)):
if (i_task + 1) % (num_tasks // 10) == 0:
tqdm.write('test {}, accuracy {:.5}'.format(i_task + 1, np.mean(test_accuracies)))
ind_train_few, Y_train_few, ind_test_few, Y_test_few = task
Z_train_few, Z_test_few = Z_test[ind_train_few], Z_test[ind_test_few]
Y_train_few, Y_test_few = keras.utils.to_categorical(Y_train_few, num_classes=num_classes), keras.utils.to_categorical(Y_test_few, num_classes=num_classes)
model = keras.Sequential()
model.add(Dense(units=units, activation='relu', input_dim=Z_train_few.shape[1]))
model.add(Dropout(rate=dropout))
model.add(Dense(units=num_classes, activation='softmax'))
model.compile(loss=categorical_crossentropy, optimizer=keras.optimizers.Adam(), metrics=['accuracy'])
early_stopping = EarlyStopping(monitor='val_loss', patience=2)
model.fit(Z_train_few, Y_train_few, batch_size=Z_train_few.shape[0], epochs=500, verbose=0, validation_data=(Z_test_few, Y_test_few), callbacks=[early_stopping])
train_score = model.evaluate(Z_train_few, Y_train_few, verbose=0)
train_accuracies.append(train_score[1])
test_score = model.evaluate(Z_test_few, Y_test_few, verbose=0)
test_accuracies.append(test_score[1])
K.clear_session()
print('units={}, dropout={}'.format(units, dropout))
print('{}-way {}-shot embedding mlp: {:.5} with 95% CI {:.5} over {} tests'.format(num_classes, num_shots, np.mean(test_accuracies), 1.96*np.std(test_accuracies)/np.sqrt(num_tasks), num_tasks))
print('Mean training accuracy: {:.5}; standard deviation: {:.5}'.format(np.mean(train_accuracies), np.std(train_accuracies)))
print('{} few-shot classification tasks: {:.5} seconds.'.format(num_tasks, time.time() - start))
示例10: cluster_color_logistic_regression
# 需要导入模块: import utils [as 别名]
# 或者: from utils import get_data [as 别名]
def cluster_color_logistic_regression(C=FLAGS.inverse_reg, penalty='l2', multi_class='multinomial', n_clusters=FLAGS.num_clusters, num_classes=FLAGS.way, num_shots=FLAGS.shot, num_tasks=FLAGS.num_tasks,
num_encoding_dims=FLAGS.num_encoding_dims, test_set=FLAGS.test_set,
dataset=FLAGS.dataset):
if dataset != 'celeba':
_, _, Z_train, X_test, Y_test, Z_test = get_data(dataset, num_encoding_dims, test_set)
else:
_, _, Z_train, X_test, attributes_test, Z_test = get_data(dataset, num_encoding_dims, test_set)
start = time.time()
kmeans = KMeans(n_clusters=n_clusters, precompute_distances=True, n_jobs=-1, n_init=100).fit(Z_train)
print("Ran KMeans with n_clusters={} in {:.5} seconds.".format(n_clusters, time.time() - start))
uniques, counts = np.unique(kmeans.labels_, return_counts=True)
if dataset != 'celeba':
task_generator = TaskGenerator(num_classes=num_classes, num_train_samples_per_class=num_shots, num_samples_per_class=num_shots+5)
partition = task_generator.get_partition_from_labels(Y_test)
partitions = [partition]
else:
task_generator = TaskGenerator(num_classes=num_classes, num_train_samples_per_class=num_shots, num_samples_per_class=num_shots+5)
partitions = task_generator.get_celeba_task_pool(attributes_test)
tasks = task_generator.get_tasks(num_tasks=num_tasks, partitions=partitions)
train_accuracies, test_accuracies = [], []
start = time.time()
clusters_to_indices = task_generator.get_partition_from_labels(kmeans.labels_)
for i_task, task in enumerate(tasks):
if (i_task + 1) % (num_tasks // 10) == 0:
print('test {}, train accuracy {:.5}, test accuracy {:.5}'.format(i_task + 1, np.mean(train_accuracies), np.mean(test_accuracies)))
ind_train_few, Y_train_few, ind_test_few, Y_test_few = task
Z_train_few, Z_test_few = Z_test[ind_train_few], Z_test[ind_test_few]
clusters_to_labels_few = defaultdict(list)
indices_to_clusters_few = kmeans.predict(Z_train_few)
for i in range(Z_train_few.shape[0]):
clusters_to_labels_few[indices_to_clusters_few[i]].append(Y_train_few[i])
Z_train_fit, Y_train_fit = [], []
for cluster in list(clusters_to_labels_few.keys()):
labels = clusters_to_labels_few[cluster]
if len(np.unique(labels)) == 1: # skip degenerate clusters
Z_train_fit.extend(Z_train[clusters_to_indices[cluster]]) # propagate labels to unlabeled datapoints
Y_train_fit.extend([labels[0] for i in range(len(clusters_to_indices[cluster]))])
Z_train_fit, Y_train_fit = np.stack(Z_train_fit, axis=0), np.stack(Y_train_fit, axis=0)
Z_train_fit = np.concatenate((Z_train_fit, Z_train_few), axis=0)
Y_train_fit = np.concatenate((Y_train_fit, Y_train_few), axis=0)
logistic_regression = LogisticRegression(n_jobs=-1, penalty=penalty, C=C, multi_class=multi_class, solver='saga', max_iter=500)
logistic_regression.fit(Z_train_fit, Y_train_fit)
test_accuracies.append(logistic_regression.score(Z_test_few, Y_test_few))
train_accuracies.append(logistic_regression.score(Z_train_fit, Y_train_fit))
print('n_clusters={}, penalty={}, C={}, multi_class={}'.format(n_clusters, penalty, C, multi_class))
print('{}-way {}-shot logistic regression after clustering: {:.5} with 95% CI {:.5} over {} tests'.format(num_classes, num_shots, np.mean(test_accuracies), 1.96*np.std(test_accuracies)/np.sqrt(num_tasks), num_tasks))
print('Mean training accuracy: {:.5}; standard deviation: {:.5}'.format(np.mean(train_accuracies), np.std(train_accuracies)))
print('{} few-shot classification tasks: {:.5} seconds.'.format(num_tasks, time.time() - start))
示例11: infer
# 需要导入模块: import utils [as 别名]
# 或者: from utils import get_data [as 别名]
def infer(data_filepath='data/flowers.hdf5', z_dim=128, out_dir='gan',
n_steps=10):
G = load_model(out_dir)
val_data = get_data(data_filepath, 'train')
val_data = next(iterate_minibatches(val_data, 2))
emb_a, emb_b = val_data[1]
txts = val_data[2]
# add batch dimension
emb_a, emb_b = emb_a[None, :], emb_b[None, :]
# sample z vector for inference
z = np.random.uniform(-1, 1, size=(1, z_dim))
G.trainable = False
# predict using embeddings a and b
fake_image_a = G.predict([z, emb_a])[0]
fake_image_b = G.predict([z, emb_b])[0]
# add and subtract
emb_add = (emb_a + emb_b)
emb_a_sub_b = (emb_a - emb_b)
emb_b_sub_a = (emb_b - emb_a)
# generate images
fake_a = G.predict([z, emb_a])[0]
fake_b = G.predict([z, emb_b])[0]
fake_add = G.predict([z, emb_add])[0]
fake_a_sub_b = G.predict([z, emb_a_sub_b])[0]
fake_b_sub_a = G.predict([z, emb_b_sub_a])[0]
fake_a = ((fake_a + 1)*0.5)
fake_b = ((fake_b + 1)*0.5)
fake_add = ((fake_add + 1)*0.5)
fake_a_sub_b = ((fake_a_sub_b + 1)*0.5)
fake_b_sub_a = ((fake_b_sub_a + 1)*0.5)
plt.imsave("{}/fake_text_arithmetic_a".format(out_dir), fake_a)
plt.imsave("{}/fake_text_arithmetic_b".format(out_dir), fake_b)
plt.imsave("{}/fake_text_arithmetic_add".format(out_dir), fake_add)
plt.imsave("{}/fake_text_arithmetic_a_sub_b".format(out_dir), fake_a_sub_b)
plt.imsave("{}/fake_text_arithmetic_b_sub_a".format(out_dir), fake_b_sub_a)
print(str(txts[0]), str(txts[1]),
file=open("{}/fake_text_arithmetic.txt".format(out_dir), "a"))
开发者ID:PacktPublishing,项目名称:Hands-On-Generative-Adversarial-Networks-with-Keras,代码行数:47,代码来源:arithmetic_in_text.py