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Ringkasan
Menunjukkan tutorial ini bagaimana menggunakan BigQuery TensorFlow pembaca untuk pelatihan jaringan syaraf menggunakan Keras berurutan API.
Himpunan data
Tutorial ini menggunakan Sensus Amerika Serikat Penghasilan Dataset disediakan oleh UC Irvine Machine Learning Repository . Kumpulan data ini berisi informasi tentang orang-orang dari database Sensus 1994, termasuk usia, pendidikan, status perkawinan, pekerjaan, dan apakah mereka menghasilkan lebih dari $50.000 setahun.
Mempersiapkan
Siapkan proyek GCP Anda
Langkah-langkah berikut diperlukan, terlepas dari lingkungan notebook Anda.
- Pilih atau buat project GCP.
- Pastikan penagihan diaktifkan untuk proyek Anda.
- Aktifkan BigQuery Storage API
- Masukkan ID proyek Anda di sel di bawah ini. Kemudian jalankan sel untuk memastikan Cloud SDK menggunakan proyek yang tepat untuk semua perintah di notebook ini.
Instal Paket yang diperlukan, dan mulai ulang runtime
try:
# Use the Colab's preinstalled TensorFlow 2.x
%tensorflow_version 2.x
except:
pass
pip install fastavropip install tensorflow-io==0.9.0
pip install google-cloud-bigquery-storage
Otentikasi
from google.colab import auth
auth.authenticate_user()
print('Authenticated')
Tetapkan ID PROYEK Anda
PROJECT_ID = "<YOUR PROJECT>"
! gcloud config set project $PROJECT_ID
%env GCLOUD_PROJECT=$PROJECT_ID
Impor pustaka Python, tentukan konstanta
from __future__ import absolute_import, division, print_function, unicode_literals
import os
from six.moves import urllib
import tempfile
import numpy as np
import pandas as pd
import tensorflow as tf
from google.cloud import bigquery
from google.api_core.exceptions import GoogleAPIError
LOCATION = 'us'
# Storage directory
DATA_DIR = os.path.join(tempfile.gettempdir(), 'census_data')
# Download options.
DATA_URL = 'https://storage.googleapis.com/cloud-samples-data/ml-engine/census/data'
TRAINING_FILE = 'adult.data.csv'
EVAL_FILE = 'adult.test.csv'
TRAINING_URL = '%s/%s' % (DATA_URL, TRAINING_FILE)
EVAL_URL = '%s/%s' % (DATA_URL, EVAL_FILE)
DATASET_ID = 'census_dataset'
TRAINING_TABLE_ID = 'census_training_table'
EVAL_TABLE_ID = 'census_eval_table'
CSV_SCHEMA = [
bigquery.SchemaField("age", "FLOAT64"),
bigquery.SchemaField("workclass", "STRING"),
bigquery.SchemaField("fnlwgt", "FLOAT64"),
bigquery.SchemaField("education", "STRING"),
bigquery.SchemaField("education_num", "FLOAT64"),
bigquery.SchemaField("marital_status", "STRING"),
bigquery.SchemaField("occupation", "STRING"),
bigquery.SchemaField("relationship", "STRING"),
bigquery.SchemaField("race", "STRING"),
bigquery.SchemaField("gender", "STRING"),
bigquery.SchemaField("capital_gain", "FLOAT64"),
bigquery.SchemaField("capital_loss", "FLOAT64"),
bigquery.SchemaField("hours_per_week", "FLOAT64"),
bigquery.SchemaField("native_country", "STRING"),
bigquery.SchemaField("income_bracket", "STRING"),
]
UNUSED_COLUMNS = ["fnlwgt", "education_num"]
Impor data sensus ke BigQuery
Tentukan metode pembantu untuk memuat data ke BigQuery
def create_bigquery_dataset_if_necessary(dataset_id):
# Construct a full Dataset object to send to the API.
client = bigquery.Client(project=PROJECT_ID)
dataset = bigquery.Dataset(bigquery.dataset.DatasetReference(PROJECT_ID, dataset_id))
dataset.location = LOCATION
try:
dataset = client.create_dataset(dataset) # API request
return True
except GoogleAPIError as err:
if err.code != 409: # http_client.CONFLICT
raise
return False
def load_data_into_bigquery(url, table_id):
create_bigquery_dataset_if_necessary(DATASET_ID)
client = bigquery.Client(project=PROJECT_ID)
dataset_ref = client.dataset(DATASET_ID)
table_ref = dataset_ref.table(table_id)
job_config = bigquery.LoadJobConfig()
job_config.write_disposition = bigquery.WriteDisposition.WRITE_TRUNCATE
job_config.source_format = bigquery.SourceFormat.CSV
job_config.schema = CSV_SCHEMA
load_job = client.load_table_from_uri(
url, table_ref, job_config=job_config
)
print("Starting job {}".format(load_job.job_id))
load_job.result() # Waits for table load to complete.
print("Job finished.")
destination_table = client.get_table(table_ref)
print("Loaded {} rows.".format(destination_table.num_rows))
Muat data Sensus di BigQuery.
load_data_into_bigquery(TRAINING_URL, TRAINING_TABLE_ID)
load_data_into_bigquery(EVAL_URL, EVAL_TABLE_ID)
Starting job 2ceffef8-e6e4-44bb-9e86-3d97b0501187 Job finished. Loaded 32561 rows. Starting job bf66f1b3-2506-408b-9009-c19f4ae9f58a Job finished. Loaded 16278 rows.
Konfirmasikan bahwa data telah diimpor
TODO: ganti <YOUR PROJECT> dengan PROJECT_ID
%%bigquery --use_bqstorage_api
SELECT * FROM `<YOUR PROJECT>.census_dataset.census_training_table` LIMIT 5
Muat data sensus di TensorFlow DataSet menggunakan pembaca BigQuery
Baca dan ubah data sensus dari BigQuery menjadi TensorFlow DataSet
from tensorflow.python.framework import ops
from tensorflow.python.framework import dtypes
from tensorflow_io.bigquery import BigQueryClient
from tensorflow_io.bigquery import BigQueryReadSession
def transform_row(row_dict):
# Trim all string tensors
trimmed_dict = { column:
(tf.strings.strip(tensor) if tensor.dtype == 'string' else tensor)
for (column,tensor) in row_dict.items()
}
# Extract feature column
income_bracket = trimmed_dict.pop('income_bracket')
# Convert feature column to 0.0/1.0
income_bracket_float = tf.cond(tf.equal(tf.strings.strip(income_bracket), '>50K'),
lambda: tf.constant(1.0),
lambda: tf.constant(0.0))
return (trimmed_dict, income_bracket_float)
def read_bigquery(table_name):
tensorflow_io_bigquery_client = BigQueryClient()
read_session = tensorflow_io_bigquery_client.read_session(
"projects/" + PROJECT_ID,
PROJECT_ID, table_name, DATASET_ID,
list(field.name for field in CSV_SCHEMA
if not field.name in UNUSED_COLUMNS),
list(dtypes.double if field.field_type == 'FLOAT64'
else dtypes.string for field in CSV_SCHEMA
if not field.name in UNUSED_COLUMNS),
requested_streams=2)
dataset = read_session.parallel_read_rows()
transformed_ds = dataset.map(transform_row)
return transformed_ds
BATCH_SIZE = 32
training_ds = read_bigquery(TRAINING_TABLE_ID).shuffle(10000).batch(BATCH_SIZE)
eval_ds = read_bigquery(EVAL_TABLE_ID).batch(BATCH_SIZE)
Tentukan kolom fitur
def get_categorical_feature_values(column):
query = 'SELECT DISTINCT TRIM({}) FROM `{}`.{}.{}'.format(column, PROJECT_ID, DATASET_ID, TRAINING_TABLE_ID)
client = bigquery.Client(project=PROJECT_ID)
dataset_ref = client.dataset(DATASET_ID)
job_config = bigquery.QueryJobConfig()
query_job = client.query(query, job_config=job_config)
result = query_job.to_dataframe()
return result.values[:,0]
from tensorflow import feature_column
feature_columns = []
# numeric cols
for header in ['capital_gain', 'capital_loss', 'hours_per_week']:
feature_columns.append(feature_column.numeric_column(header))
# categorical cols
for header in ['workclass', 'marital_status', 'occupation', 'relationship',
'race', 'native_country', 'education']:
categorical_feature = feature_column.categorical_column_with_vocabulary_list(
header, get_categorical_feature_values(header))
categorical_feature_one_hot = feature_column.indicator_column(categorical_feature)
feature_columns.append(categorical_feature_one_hot)
# bucketized cols
age = feature_column.numeric_column('age')
age_buckets = feature_column.bucketized_column(age, boundaries=[18, 25, 30, 35, 40, 45, 50, 55, 60, 65])
feature_columns.append(age_buckets)
feature_layer = tf.keras.layers.DenseFeatures(feature_columns)
Bangun dan latih model
Membangun model
Dense = tf.keras.layers.Dense
model = tf.keras.Sequential(
[
feature_layer,
Dense(100, activation=tf.nn.relu, kernel_initializer='uniform'),
Dense(75, activation=tf.nn.relu),
Dense(50, activation=tf.nn.relu),
Dense(25, activation=tf.nn.relu),
Dense(1, activation=tf.nn.sigmoid)
])
# Compile Keras model
model.compile(
loss='binary_crossentropy',
metrics=['accuracy'])
Model kereta api
model.fit(training_ds, epochs=5)
WARNING:tensorflow:Layer sequential is casting an input tensor from dtype float64 to the layer's dtype of float32, which is new behavior in TensorFlow 2. The layer has dtype float32 because it's dtype defaults to floatx.
If you intended to run this layer in float32, you can safely ignore this warning. If in doubt, this warning is likely only an issue if you are porting a TensorFlow 1.X model to TensorFlow 2.
To change all layers to have dtype float64 by default, call `tf.keras.backend.set_floatx('float64')`. To change just this layer, pass dtype='float64' to the layer constructor. If you are the author of this layer, you can disable autocasting by passing autocast=False to the base Layer constructor.
WARNING:tensorflow:From /usr/local/lib/python3.6/dist-packages/tensorflow_core/python/feature_column/feature_column_v2.py:4276: IndicatorColumn._variable_shape (from tensorflow.python.feature_column.feature_column_v2) is deprecated and will be removed in a future version.
Instructions for updating:
The old _FeatureColumn APIs are being deprecated. Please use the new FeatureColumn APIs instead.
WARNING:tensorflow:From /usr/local/lib/python3.6/dist-packages/tensorflow_core/python/feature_column/feature_column_v2.py:4331: VocabularyListCategoricalColumn._num_buckets (from tensorflow.python.feature_column.feature_column_v2) is deprecated and will be removed in a future version.
Instructions for updating:
The old _FeatureColumn APIs are being deprecated. Please use the new FeatureColumn APIs instead.
Epoch 1/5
1018/1018 [==============================] - 17s 17ms/step - loss: 0.5985 - accuracy: 0.8105
Epoch 2/5
1018/1018 [==============================] - 10s 10ms/step - loss: 0.3670 - accuracy: 0.8324
Epoch 3/5
1018/1018 [==============================] - 11s 10ms/step - loss: 0.3487 - accuracy: 0.8393
Epoch 4/5
1018/1018 [==============================] - 11s 10ms/step - loss: 0.3398 - accuracy: 0.8435
Epoch 5/5
1018/1018 [==============================] - 11s 11ms/step - loss: 0.3377 - accuracy: 0.8455
<tensorflow.python.keras.callbacks.History at 0x7f978f5b91d0>
Evaluasi model
Evaluasi model
loss, accuracy = model.evaluate(eval_ds)
print("Accuracy", accuracy)
509/509 [==============================] - 8s 15ms/step - loss: 0.3338 - accuracy: 0.8398 Accuracy 0.8398452
Evaluasi beberapa sampel acak
sample_x = {
'age' : np.array([56, 36]),
'workclass': np.array(['Local-gov', 'Private']),
'education': np.array(['Bachelors', 'Bachelors']),
'marital_status': np.array(['Married-civ-spouse', 'Married-civ-spouse']),
'occupation': np.array(['Tech-support', 'Other-service']),
'relationship': np.array(['Husband', 'Husband']),
'race': np.array(['White', 'Black']),
'gender': np.array(['Male', 'Male']),
'capital_gain': np.array([0, 7298]),
'capital_loss': np.array([0, 0]),
'hours_per_week': np.array([40, 36]),
'native_country': np.array(['United-States', 'United-States'])
}
model.predict(sample_x)
array([[0.5541261],
[0.6209938]], dtype=float32)