TensorFlow-CIFAR10 CNN代码分析

2021-10-19 16:25:49 浏览数 (1)

根据TensorFlow 1.2.1,改了官方版本的报错。

CIFAR

想了解更多信息请参考CIFAR-10 page,以及Alex Krizhevsky写的技术报告

  • 相关核心数学对象,如卷积、修正线性激活、最大池化以及局部响应归一化;
  • 训练过程中一些网络行为的可视化,这些行为包括输入图像、损失情况、网络行为的分布情况以及梯度;
  • 算法学习参数的移动平均值的计算函数,以及在评估阶段使用这些平均值提高预测性能;
  • 实现了一种机制,使得学习率随着时间的推移而递减;
  • 为输入数据设计预存取队列,将磁盘延迟和高开销的图像预处理操作与模型分离开来处理;

代码组织

文件

作用

cifar10_input.py

读取本地CIFAR-10的二进制文件格式的内容。

cifar10.py

建立CIFAR-10的模型。

cifar10_train.py

在CPU或GPU上训练CIFAR-10的模型。

cifar10_multi_gpu_train.py

在多GPU上训练CIFAR-10的模型。

cifar10_eval.py

评估CIFAR-10模型的预测性能。

代码分析

由于TensorFlow 1.0有些版本改动,导致新版本和以前代码不兼容,具体bug解决方法见:TensorFlow CIFAR-10训练例子报错解决

下面是其官方的训练效果。10万步的准确率为86%左右,所以其实并不用训练到100k。

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System        | Step Time (sec/batch)  |     Accuracy
------------------------------------------------------------------
1 Tesla K20m  | 0.35-0.60              | ~86% at 60K steps  (5 hours)
1 Tesla K40m  | 0.25-0.35              | ~86% at 100K steps (4 hours)

cifar10_train.py

代码核心的train()函数,如下:

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def train():
    """Train CIFAR-10 for a number of steps."""
    with tf.Graph().as_default():
        global_step = tf.Variable(0, trainable=False)

        # Get images and labels for CIFAR-10.
        # 输入图像的预处理,包括亮度、对比度、图像翻转等操作
        images, labels = cifar10.distorted_inputs()

        # Build a Graph that computes the logits predictions from the
        # inference model.
        logits = cifar10.inference(images)

        # Calculate loss.
        loss = cifar10.loss(logits, labels)

        # Build a Graph that trains the model with one batch of examples and
        # updates the model parameters.
        train_op = cifar10.train(loss, global_step)

        # Create a saver.
        saver = tf.train.Saver(tf.all_variables())

        # Build the summary operation based on the TF collection of Summaries.
        summary_op = tf.summary.merge_all()

        # Build an initialization operation to run below.
        init = tf.initialize_all_variables()

        # Start running operations on the Graph.
        sess = tf.Session(config=tf.ConfigProto(
            log_device_placement=FLAGS.log_device_placement))
        sess.run(init)

        # Start the queue runners.
        tf.train.start_queue_runners(sess=sess)

        summary_writer = tf.summary.FileWriter(FLAGS.train_dir,
                                               graph_def=sess.graph_def)
        # 按照设置的迭代次数迭代
        for step in xrange(FLAGS.max_steps):
            start_time = time.time()
            _, loss_value = sess.run([train_op, loss])
            duration = time.time() - start_time

            assert not np.isnan(loss_value), 'Model diverged with loss = NaN'
            # 每10个输入数据显示次step,loss,时间等运行数据
            if step % 10 == 0:
                num_examples_per_step = FLAGS.batch_size
                examples_per_sec = num_examples_per_step / duration
                sec_per_batch = float(duration)

                format_str = ('%s: step %d, loss = %.2f (%.1f examples/sec; %.3f '
                              'sec/batch)')
                print(format_str % (datetime.now(), step, loss_value,
                                    examples_per_sec, sec_per_batch))
            # 每100个输入数据将网络的状况体现在summary里
            if step % 100 == 0:
                summary_str = sess.run(summary_op)
                summary_writer.add_summary(summary_str, step)

            # Save the model checkpoint periodically.
            # 每1000个输入数据保存次模型
            if step % 1000 == 0 or (step   1) == FLAGS.max_steps:
                checkpoint_path = os.path.join(FLAGS.train_dir, 'model.ckpt')
                saver.save(sess, checkpoint_path, global_step=step)


def main(argv=None):  # pylint: disable=unused-argument
    # 检查目录下是否有数据,没有则下载。
    cifar10.maybe_download_and_extract()
    # 删除训练日志。
    if gfile.Exists(FLAGS.train_dir):
        gfile.DeleteRecursively(FLAGS.train_dir)
    gfile.MakeDirs(FLAGS.train_dir)
    # 训练
    train()


if __name__ == '__main__':
    # 处理flag解析,并执行main函数。
    tf.app.run()

其中的distorded_inputs函数,对训练集合进行随机的一些操作,包括颠倒,随机翻转等,以保证包含验证集中情况。在cifar10_input.py中,具体代码如下:

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def distorted_inputs(data_dir, batch_size):
    """Construct distorted input for CIFAR training using the Reader ops.

    Args:
      data_dir: Path to the CIFAR-10 data directory.
      batch_size: Number of images per batch.

    Returns:
      images: Images. 4D tensor of [batch_size, IMAGE_SIZE, IMAGE_SIZE, 3] size.
      labels: Labels. 1D tensor of [batch_size] size.
    """
    # 训练集合具有更多随机的操作,包括颠倒,随机翻转,以保证包含验证集中情况。
    filenames = [os.path.join(data_dir, 'data_batch_%d.bin' % i)
                 for i in xrange(1, 6)]
    for f in filenames:
        if not gfile.Exists(f):
            raise ValueError('Failed to find file: '   f)

    # Create a queue that produces the filenames to read.
    filename_queue = tf.train.string_input_producer(filenames)

    # Read examples from files in the filename queue.
    read_input = read_cifar10(filename_queue)
    reshaped_image = tf.cast(read_input.uint8image, tf.float32)

    height = IMAGE_SIZE
    width = IMAGE_SIZE

    # Image processing for training the network. Note the many random
    # distortions applied to the image.

    # 步骤1:随机截取一个以[高,宽]为大小的图矩阵。
    distorted_image = tf.random_crop(reshaped_image, [height, width, 3])

    # 步骤2:随机颠倒图片的左右。概率为50%
    distorted_image = tf.image.random_flip_left_right(distorted_image)

    # Because these operations are not commutative, consider randomizing
    # randomize the order their operation.
    #  步骤3:随机改变图片的亮度以及色彩对比。
    distorted_image = tf.image.random_brightness(distorted_image,
                                                 max_delta=63)
    distorted_image = tf.image.random_contrast(distorted_image,
                                               lower=0.2, upper=1.8)

    # Subtract off the mean and divide by the variance of the pixels.
    float_image = tf.image.per_image_standardization(distorted_image)

    # Ensure that the random shuffling has good mixing properties.
    # queue里有了不少于40%的数据的时候训练才能开始
    min_fraction_of_examples_in_queue = 0.4
    min_queue_examples = int(NUM_EXAMPLES_PER_EPOCH_FOR_TRAIN *
                             min_fraction_of_examples_in_queue)
    print('Filling queue with %d CIFAR images before starting to train. '
          'This will take a few minutes.' % min_queue_examples)

    # Generate a batch of images and labels by building up a queue of examples.
    return _generate_image_and_label_batch(float_image, read_input.label,
                                           min_queue_examples, batch_size)

而对于验证集,不需要上述操作,所以使用inputs()函数,基本和上面相似,不赘述了,在cifar10_input.py中,具体代码如下:

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def inputs(eval_data, data_dir, batch_size):
    """Construct input for CIFAR evaluation using the Reader ops.

    Args:
      eval_data: bool, indicating if one should use the train or eval data set.
      data_dir: Path to the CIFAR-10 data directory.
      batch_size: Number of images per batch.

    Returns:
      images: Images. 4D tensor of [batch_size, IMAGE_SIZE, IMAGE_SIZE, 3] size.
      labels: Labels. 1D tensor of [batch_size] size.
    """
    if not eval_data:
        filenames = [os.path.join(data_dir, 'data_batch_%d.bin' % i)
                     for i in xrange(1, 6)]
        num_examples_per_epoch = NUM_EXAMPLES_PER_EPOCH_FOR_TRAIN
    else:
        filenames = [os.path.join(data_dir, 'test_batch.bin')]
        num_examples_per_epoch = NUM_EXAMPLES_PER_EPOCH_FOR_EVAL

    for f in filenames:
        if not gfile.Exists(f):
            raise ValueError('Failed to find file: '   f)

    # Create a queue that produces the filenames to read.
    filename_queue = tf.train.string_input_producer(filenames)

    # Read examples from files in the filename queue.
    read_input = read_cifar10(filename_queue)
    reshaped_image = tf.cast(read_input.uint8image, tf.float32)

    height = IMAGE_SIZE
    width = IMAGE_SIZE

    # Image processing for evaluation.
    # Crop the central [height, width] of the image.
    resized_image = tf.image.resize_image_with_crop_or_pad(reshaped_image,
                                                           width, height)

    # Subtract off the mean and divide by the variance of the pixels.
    float_image = tf.image.per_image_standardization(resized_image)

    # Ensure that the random shuffling has good mixing properties.
    min_fraction_of_examples_in_queue = 0.4
    min_queue_examples = int(num_examples_per_epoch *
                             min_fraction_of_examples_in_queue)

    # Generate a batch of images and labels by building up a queue of examples.
    return _generate_image_and_label_batch(float_image, read_input.label, min_queue_examples, batch_size)

cifar10.py

这一部分是训练CNN模型的代码,inference()函数主要是定义CNN结构,在MINIST中已经详细解释过,参考tensorFlow搭建CNN-mnist上手:

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def inference(images):
    """Build the CIFAR-10 model.
    Args:
      images: Images returned from distorted_inputs() or inputs().
    Returns:
      Logits.
    """
    # We instantiate all variables using tf.get_variable() instead of
    # tf.Variable() in order to share variables across multiple GPU training runs.
    # If we only ran this model on a single GPU, we could simplify this function
    # by replacing all instances of tf.get_variable() with tf.Variable().
    #
    # conv1
    with tf.variable_scope('conv1') as scope:
        kernel = _variable_with_weight_decay('weights', shape=[5, 5, 3, 64],
                                             stddev=1e-4, wd=0.0)
        conv = tf.nn.conv2d(images, kernel, [1, 1, 1, 1], padding='SAME')
        biases = _variable_on_cpu('biases', [64], tf.constant_initializer(0.0))
        bias = tf.nn.bias_add(conv, biases)
        conv1 = tf.nn.relu(bias, name=scope.name)
        _activation_summary(conv1)

    # pool1
    pool1 = tf.nn.max_pool(conv1, ksize=[1, 3, 3, 1], strides=[1, 2, 2, 1],
                           padding='SAME', name='pool1')
    # norm1
    norm1 = tf.nn.lrn(pool1, 4, bias=1.0, alpha=0.001 / 9.0, beta=0.75,
                      name='norm1')

    # conv2
    with tf.variable_scope('conv2') as scope:
        kernel = _variable_with_weight_decay('weights', shape=[5, 5, 64, 64],
                                             stddev=1e-4, wd=0.0)
        conv = tf.nn.conv2d(norm1, kernel, [1, 1, 1, 1], padding='SAME')
        biases = _variable_on_cpu('biases', [64], tf.constant_initializer(0.1))
        bias = tf.nn.bias_add(conv, biases)
        conv2 = tf.nn.relu(bias, name=scope.name)
        _activation_summary(conv2)

    # norm2
    norm2 = tf.nn.lrn(conv2, 4, bias=1.0, alpha=0.001 / 9.0, beta=0.75,
                      name='norm2')
    # pool2
    pool2 = tf.nn.max_pool(norm2, ksize=[1, 3, 3, 1],
                           strides=[1, 2, 2, 1], padding='SAME', name='pool2')

    # local3
    with tf.variable_scope('local3') as scope:
        # Move everything into depth so we can perform a single matrix multiply.
        dim = 1
        for d in pool2.get_shape()[1:].as_list():
            dim *= d
        reshape = tf.reshape(pool2, [FLAGS.batch_size, dim])

        weights = _variable_with_weight_decay('weights', shape=[dim, 384],
                                              stddev=0.04, wd=0.004)
        biases = _variable_on_cpu('biases', [384], tf.constant_initializer(0.1))
        local3 = tf.nn.relu(tf.matmul(reshape, weights)   biases, name=scope.name)
        _activation_summary(local3)

    # local4
    with tf.variable_scope('local4') as scope:
        weights = _variable_with_weight_decay('weights', shape=[384, 192],
                                              stddev=0.04, wd=0.004)
        biases = _variable_on_cpu('biases', [192], tf.constant_initializer(0.1))
        local4 = tf.nn.relu(tf.matmul(local3, weights)   biases, name=scope.name)
        _activation_summary(local4)

    # softmax, i.e. softmax(WX   b)
    with tf.variable_scope('softmax_linear') as scope:
        weights = _variable_with_weight_decay('weights', [192, NUM_CLASSES],
                                              stddev=1 / 192.0, wd=0.0)
        biases = _variable_on_cpu('biases', [NUM_CLASSES],
                                  tf.constant_initializer(0.0))
        softmax_linear = tf.add(tf.matmul(local4, weights), biases, name=scope.name)
        _activation_summary(softmax_linear)

    return softmax_linear

训练CNN,train()函数:

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def train(total_loss, global_step):
    """Train CIFAR-10 model.

    Create an optimizer and apply to all trainable variables. Add moving
    average for all trainable variables.

    Args:
      total_loss: Total loss from loss().
      global_step: Integer Variable counting the number of training steps
        processed.
    Returns:
      train_op: op for training.
    """
    # Variables that affect learning rate.
    num_batches_per_epoch = NUM_EXAMPLES_PER_EPOCH_FOR_TRAIN / FLAGS.batch_size
    decay_steps = int(num_batches_per_epoch * NUM_EPOCHS_PER_DECAY)

    # Decay the learning rate exponentially based on the number of steps.
    lr = tf.train.exponential_decay(INITIAL_LEARNING_RATE,
                                    global_step,
                                    decay_steps,
                                    LEARNING_RATE_DECAY_FACTOR,
                                    staircase=True)
    tf.summary.scalar('learning_rate', lr)

    # Generate moving averages of all losses and associated summaries.
    loss_averages_op = _add_loss_summaries(total_loss)

    # Compute gradients.
    # control dependencies的运用。这里只有loss_averages_op完成了
    # 我们才会进行gradient descent的优化。
    with tf.control_dependencies([loss_averages_op]):
        opt = tf.train.GradientDescentOptimizer(lr)
        grads = opt.compute_gradients(total_loss)

    # Apply gradients.
    apply_gradient_op = opt.apply_gradients(grads, global_step=global_step)

    # Add histograms for trainable variables.
    for var in tf.trainable_variables():
        tf.summary.histogram(var.op.name, var)

    # Add histograms for gradients.
    for grad, var in grads:
        if grad is not None:
            tf.summary.histogram(var.op.name   '/gradients', grad)

    # Track the moving averages of all trainable variables.
    variable_averages = tf.train.ExponentialMovingAverage(
        MOVING_AVERAGE_DECAY, global_step)
    variables_averages_op = variable_averages.apply(tf.trainable_variables())

    with tf.control_dependencies([apply_gradient_op, variables_averages_op]):
        train_op = tf.no_op(name='train')

    return train_op

cifar10_eval.py

然后是评估函数evaluate():

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def evaluate():
  """Eval CIFAR-10 for a number of steps."""
  with tf.Graph().as_default():
    # Get images and labels for CIFAR-10.
    eval_data = FLAGS.eval_data == 'test'
    images, labels = cifar10.inputs(eval_data=eval_data)

    # Build a Graph that computes the logits predictions from the
    # inference model.
    logits = cifar10.inference(images)

    # Calculate predictions.
    top_k_op = tf.nn.in_top_k(logits, labels, 1)

    # Restore the moving average version of the learned variables for eval.
    variable_averages = tf.train.ExponentialMovingAverage(
        cifar10.MOVING_AVERAGE_DECAY)
    variables_to_restore = variable_averages.variables_to_restore()
    saver = tf.train.Saver(variables_to_restore)

    # Build the summary operation based on the TF collection of Summaries.
    summary_op = tf.summary.merge_all()

    graph_def = tf.get_default_graph().as_graph_def()
    summary_writer = tf.summary.FileWriter(FLAGS.eval_dir,
                                            graph_def=graph_def)

    while True:
      eval_once(saver, summary_writer, top_k_op, summary_op)
      if FLAGS.run_once:
        break
      time.sleep(FLAGS.eval_interval_secs)

主线就是这样,具体代码见:CIFAR_TensorFlow

Reference

卷积神经网络

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