Python costの例

コード例 #1

def train_multi_label_tfRecords(
        train_file_tfRecord, valid_file_tfRecord, train_dir, num_classes,
        batch_size, arch_model, learning_r_decay, learning_rate_base,
        decay_rate, dropout_prob, epoch, height, width,
        checkpoint_exclude_scopes, early_stop, EARLY_STOP_PATIENCE, fine_tune,
        train_all_layers, checkpoint_path, train_n, valid_n, g_parameter):
    # ---------------------------------------------------------------------------------#
    print(train_file_tfRecord)
    train_image_filename_queue = tf.train.string_input_producer(
        tf.train.match_filenames_once(train_file_tfRecord))
    train_images, train_labels = read_image_batch(train_image_filename_queue,
                                                  num_classes, batch_size,
                                                  height, width)
    valid_image_filename_queue = tf.train.string_input_producer(
        tf.train.match_filenames_once(valid_file_tfRecord))
    valid_images, valid_labels = read_image_batch(valid_image_filename_queue,
                                                  num_classes, batch_size,
                                                  height, width)
    # ---------------------------------------------------------------------------------#
    X, Y, is_train, keep_prob_fc = input_placeholder(height, width,
                                                     num_classes)
    net, _ = build_net_multi_label(X, num_classes, keep_prob_fc, is_train,
                                   arch_model)
    variables_to_restore, variables_to_train = g_parameter(
        checkpoint_exclude_scopes)
    loss = cost(Y, net)
    global_step = tf.Variable(0, trainable=False)
    if learning_r_decay:
        learning_rate = tf.train.exponential_decay(learning_rate_base,
                                                   global_step * batch_size,
                                                   train_n,
                                                   decay_rate,
                                                   staircase=True)
    else:
        learning_rate = learning_rate_base
    if train_all_layers:
        variables_to_train = []
    optimizer = train_op(learning_rate, loss, variables_to_train, global_step)
    pre = tf.nn.sigmoid(net)
    accuracy = model_mAP(pre, Y)
    #------------------------------------------------------------------------------------#
    sess = tf.InteractiveSession()
    tf.local_variables_initializer().run()
    tf.global_variables_initializer().run()
    #init = tf.global_variables_initializer()
    #sess.run(init)
    saver2 = tf.train.Saver(tf.global_variables())
    if not train_all_layers:
        saver_net = tf.train.Saver(variables_to_restore)
        saver_net.restore(sess, checkpoint_path)

    if fine_tune:
        # saver2.restore(sess, fine_tune_dir)
        latest = tf.train.latest_checkpoint(train_dir)
        if not latest:
            print("No checkpoint to continue from in", train_dir)
            sys.exit(1)
        print("resume", latest)
        saver2.restore(sess, latest)

    # early stopping
    best_valid = np.inf
    best_valid_epoch = 0

    # start queue runner
    coord = tf.train.Coordinator()
    threads = tf.train.start_queue_runners(sess=sess, coord=coord)
    for epoch_i in range(epoch):
        for batch_i in range(int(train_n / batch_size)):
            train_image = tf.image.resize_images(train_images, (height, width),
                                                 method=0)
            train_image = (tf.cast(train_image, tf.float32) / 255 - 0.5) * 2
            train_image, train_label = sess.run([train_image, train_labels])
            # print (train_image)
            # print (train_label)
            los, _ = sess.run(
                [loss, optimizer],
                feed_dict={
                    X: train_image,
                    Y: train_label,
                    is_train: True,
                    keep_prob_fc: dropout_prob
                })
            # print (los)
            #checkpoint_path = os.path.join(train_dir, 'model.ckpt')
            #saver2.save(sess, checkpoint_path, global_step=batch_i, write_meta_graph=False)
            if batch_i % 100 == 0:
                loss_, acc_ = sess.run(
                    [loss, accuracy],
                    feed_dict={
                        X: train_image,
                        Y: train_label,
                        is_train: False,
                        keep_prob_fc: 1.0
                    })
                print(
                    'Batch: {:>2}: Training loss: {:>3.5f}, Training mAP: {:>3.5f}'
                    .format(batch_i, loss_, acc_))

            if batch_i % 500 == 0:
                valid_image = tf.image.resize_images(valid_images,
                                                     (height, width),
                                                     method=0)
                valid_image = (tf.cast(valid_image, tf.float32) / 255 -
                               0.5) * 2
                valid_image, valid_label = sess.run(
                    [valid_image, valid_labels])
                ls, acc = sess.run(
                    [loss, accuracy],
                    feed_dict={
                        X: valid_image,
                        Y: valid_label,
                        is_train: False,
                        keep_prob_fc: 1.0
                    })
                print(
                    'Batch: {:>2}: Validation loss: {:>3.5f}, Validation mAP: {:>3.5f}'
                    .format(batch_i, ls, acc))
            if batch_i % 500 == 0:
                checkpoint_path = os.path.join(train_dir, 'model.ckpt')
                saver2.save(sess,
                            checkpoint_path,
                            global_step=batch_i,
                            write_meta_graph=False)

        print(
            'Epoch===================================>: {:>2}'.format(epoch_i))
        valid_ls = 0
        valid_acc = 0
        for batch_i in range(int(valid_n / batch_size)):
            valid_image = tf.image.resize_images(valid_images, (height, width),
                                                 method=0)
            valid_image = (tf.cast(valid_image, tf.float32) / 255 - 0.5) * 2
            valid_image, valid_label = sess.run([valid_image, valid_labels])
            # images_valid, labels_valid = get_next_batch_from_path(valid_image, valid_label, batch_i, height, width, batch_size=batch_size, training=False)
            epoch_ls, epoch_acc = sess.run([loss, accuracy],
                                           feed_dict={
                                               X: valid_image,
                                               Y: valid_label,
                                               keep_prob_fc: 1.0,
                                               is_train: False
                                           })
            valid_ls = valid_ls + epoch_ls
            valid_acc = valid_acc + epoch_acc
        print(
            'Epoch: {:>2}: Validation loss: {:>3.5f}, Validation mAP: {:>3.5f}'
            .format(epoch_i, valid_ls / int(valid_n / batch_size),
                    valid_acc / int(valid_n / batch_size)))

        if valid_acc / int(valid_n / batch_size) > 0.90:
            checkpoint_path = os.path.join(train_dir, 'model.ckpt')
            saver2.save(sess,
                        checkpoint_path,
                        global_step=epoch_i,
                        write_meta_graph=False)
        # ---------------------------------------------------------------------------------#
        if early_stop:
            loss_valid = valid_ls / int(valid_n / batch_size)
            if loss_valid < best_valid:
                best_valid = loss_valid
                best_valid_epoch = epoch_i
            elif best_valid_epoch + EARLY_STOP_PATIENCE < epoch_i:
                print("Early stopping.")
                print("Best valid loss was {:.6f} at epoch {}.".format(
                    best_valid, best_valid_epoch))
                break
        # train_data, train_label = shuffle_train_data(train_data, train_label)
    # stop queue runner
    coord.request_stop()
    coord.join(threads)
    sess.close()

コード例 #2

height, width = config.height, config.width
arch_model = config.arch_model
batch_size = config.batch_size
sample_dir = 'val.txt'
train_rate = 1.0
test_data, test_label, valid_data, valid_label, test_n, valid_n, note_label = data_load_from_txt_mullabel(
    sample_dir, train_rate).gen_train_valid()
print('test_n', test_n)
print('valid_n', valid_n)
# test_label = np_utils.to_categorical(test_label, num_classes)
# valid_label = np_utils.to_categorical(valid_label, num_classes)

X, Y, is_train, keep_prob_fc = input_placeholder(height, width, num_classes)
net, _ = build_net_multi_label(X, num_classes, keep_prob_fc, is_train,
                               arch_model)
loss = cost(Y, net)
pre = tf.nn.sigmoid(net)
accuracy = model_mAP(pre, Y)
# predict = tf.reshape(net, [-1, num_classes], name='predictions')

if __name__ == '__main__':
    train_dir = 'model'
    latest = tf.train.latest_checkpoint(train_dir)
    if not latest:
        print("No checkpoint to continue from in", train_dir)
        sys.exit(1)
    print("resume", latest)
    sess = tf.Session()
    saver = tf.train.Saver(tf.global_variables())
    saver.restore(sess, latest)
    test_ls = 0

コード例 #3

ファイル: train_multi_label.py プロジェクト: dukeyuan/train_cnn_multilabel

def train_multi_label(train_data, train_label, valid_data, valid_label,
                      train_dir, num_classes, batch_size, arch_model,
                      learning_r_decay, learning_rate_base, decay_rate,
                      dropout_prob, epoch, height, width,
                      checkpoint_exclude_scopes, early_stop,
                      EARLY_STOP_PATIENCE, fine_tune, train_all_layers,
                      checkpoint_path, train_n, valid_n, g_parameter):
    # ---------------------------------------------------------------------------------#
    X, Y, is_train, keep_prob_fc = input_placeholder(height, width,
                                                     num_classes)
    net, _ = build_net_multi_label(X, num_classes, keep_prob_fc, is_train,
                                   arch_model)
    variables_to_restore, variables_to_train = g_parameter(
        checkpoint_exclude_scopes)
    loss = cost(Y, net)
    global_step = tf.Variable(0, trainable=False)
    if learning_r_decay:
        learning_rate = tf.train.exponential_decay(learning_rate_base,
                                                   global_step * batch_size,
                                                   train_n,
                                                   decay_rate,
                                                   staircase=True)
    else:
        learning_rate = learning_rate_base
    if train_all_layers:
        variables_to_train = []
    optimizer = train_op(learning_rate, loss, variables_to_train, global_step)
    accuracy = model_mAP(net, Y)
    #------------------------------------------------------------------------------------#
    sess = tf.Session()
    init = tf.global_variables_initializer()
    sess.run(init)
    saver2 = tf.train.Saver(tf.global_variables())
    if not train_all_layers:
        saver_net = tf.train.Saver(variables_to_restore)
        saver_net.restore(sess, checkpoint_path)

    if fine_tune:
        # saver2.restore(sess, fine_tune_dir)
        latest = tf.train.latest_checkpoint(train_dir)
        if not latest:
            print("No checkpoint to continue from in", train_dir)
            sys.exit(1)
        print("resume", latest)
        saver2.restore(sess, latest)

    # early stopping
    best_valid = np.inf
    best_valid_epoch = 0

    for epoch_i in range(epoch):
        for batch_i in range(int(train_n / batch_size)):
            images, labels = get_next_batch_from_path(train_data,
                                                      train_label,
                                                      batch_i,
                                                      height,
                                                      width,
                                                      batch_size=batch_size,
                                                      training=True)
            los, _ = sess.run([loss, optimizer],
                              feed_dict={
                                  X: images,
                                  Y: labels,
                                  is_train: True,
                                  keep_prob_fc: dropout_prob
                              })
            print(los)
            checkpoint_path = os.path.join(train_dir, 'model.ckpt')
            saver2.save(sess,
                        checkpoint_path,
                        global_step=batch_i,
                        write_meta_graph=False)
            if batch_i % 20 == 0:
                loss_, acc_ = sess.run([loss, accuracy],
                                       feed_dict={
                                           X: images,
                                           Y: labels,
                                           is_train: False,
                                           keep_prob_fc: 1.0
                                       })
                print(
                    'Batch: {:>2}: Training loss: {:>3.5f}, Training mAP: {:>3.5f}'
                    .format(batch_i, loss_, acc_))

            if batch_i % 100 == 0:
                images, labels = get_next_batch_from_path(
                    valid_data,
                    valid_label,
                    batch_i % (int(valid_n / batch_size)),
                    height,
                    width,
                    batch_size=batch_size,
                    training=False)
                ls, acc = sess.run([loss, accuracy],
                                   feed_dict={
                                       X: images,
                                       Y: labels,
                                       is_train: False,
                                       keep_prob_fc: 1.0
                                   })
                print(
                    'Batch: {:>2}: Validation loss: {:>3.5f}, Validation mAP: {:>3.5f}'
                    .format(batch_i, ls, acc))

        print(
            'Epoch===================================>: {:>2}'.format(epoch_i))
        valid_ls = 0
        valid_acc = 0
        for batch_i in range(int(valid_n / batch_size)):
            images_valid, labels_valid = get_next_batch_from_path(
                valid_data,
                valid_label,
                batch_i,
                height,
                width,
                batch_size=batch_size,
                training=False)
            epoch_ls, epoch_acc = sess.run(
                [loss, accuracy],
                feed_dict={
                    X: images_valid,
                    Y: labels_valid,
                    keep_prob_fc: 1.0,
                    is_train: False
                })
            valid_ls = valid_ls + epoch_ls
            valid_acc = valid_acc + epoch_acc
        print(
            'Epoch: {:>2}: Validation loss: {:>3.5f}, Validation mAP: {:>3.5f}'
            .format(epoch_i, valid_ls / int(valid_n / batch_size),
                    valid_acc / int(valid_n / batch_size)))

        if valid_acc / int(valid_n / batch_size) > 0.90:
            checkpoint_path = os.path.join(train_dir, 'model.ckpt')
            saver2.save(sess,
                        checkpoint_path,
                        global_step=epoch_i,
                        write_meta_graph=False)
        # ---------------------------------------------------------------------------------#
        if early_stop:
            loss_valid = valid_ls / int(valid_n / batch_size)
            if loss_valid < best_valid:
                best_valid = loss_valid
                best_valid_epoch = epoch_i
            elif best_valid_epoch + EARLY_STOP_PATIENCE < epoch_i:
                print("Early stopping.")
                print("Best valid loss was {:.6f} at epoch {}.".format(
                    best_valid, best_valid_epoch))
                break
        train_data, train_label = shuffle_train_data(train_data, train_label)
    sess.close()