• 学习笔记TF063:TensorFlow Debugger


    TensorFlow Debugger(tfdbg),TensorFlow专用调试器。用断点、计算机图形化展现实时数据流,可视化运行TensorFlow图形内部结构、状态。有助训练推理调试模型错误。https://www.tensorflow.org/programmers_guide/debugger 。

    常见错误类型,非数字(nan)、无限值(inf)。tfdbg命令行界面(command line interface,CLI)。

    Debugger示例。错误运行MNIST训练,通过TensorFlow Debugger找到出错地方,改正。https://github.com/tensorflow/tensorflow/blob/master/tensorflow/python/debug/examples/debug_mnist.py 。

    先直接执行。

    python -m tensorflow.python.debug.examples.debug_mnist

    准确率第一次训练上千,后面保持较低水平。
    TensorFlow Debugger,在每次调用run()前后基于终端用户界面(UI),控制执行、检查图内部状态。

    from tensorflow.python import debug as tf_debug
    sess = tr.debug.LocalCLIDebugWrapperSession(sess)
    sess.add_tensor_filter("has_inf_or_nan", tf_debug.has_inf_or_nan)

    张量值注册过滤器has_inf_on_nan,判断图中间张量是否有nan、inf值。
    开启调试模式(debug)。

    python -m tensorflow.python.debug.examples.debug_mnist -debug
    python debug_mnist.py --debug=True

    运行开始UI(run-start UI),在tfdbg>后输入交互式命令,run()进入运行结束后UI(run-end UI)。连续运行10次

    tfdbg>run -t 10
    找出图形第一个nan或inf值

    tfdbg> run -f has_inf_or_nan

    第一行灰底字表示tfdbg在调用run()后立即停止,生成指定过滤器has_inf_or_nan中间张量。第4次调用run(),36个中间张量包含inf或nan值。首次出现在cross_entropy/Log:0。单击图中cross_entropy/Log:0,单击下划线node_info菜单项,看节点输入张量,是否有0值。

    tfdbg>pt softmax/Softmax:0

    用ni命令-t标志追溯
    ni -t cross_entropy/Log
    问题代码

    diff = -(y_ * tf.log(y))
    修改,对tf.log输入值裁剪

    diff = y_ * tf.log(tf.clip_by_value(y, 1e-8, 1.0))

    from __future__ import absolute_import
    from __future__ import division
    from __future__ import print_function
    import argparse
    import sys
    import tensorflow as tf
    from tensorflow.examples.tutorials.mnist import input_data
    from tensorflow.python import debug as tf_debug
    IMAGE_SIZE = 28
    HIDDEN_SIZE = 500
    NUM_LABELS = 10
    RAND_SEED = 42
    def main(_):
    # Import data
    mnist = input_data.read_data_sets(FLAGS.data_dir,
    one_hot=True,
    fake_data=FLAGS.fake_data)
    def feed_dict(train):
    if train or FLAGS.fake_data:
    xs, ys = mnist.train.next_batch(FLAGS.train_batch_size,
    fake_data=FLAGS.fake_data)
    else:
    xs, ys = mnist.test.images, mnist.test.labels
    return {x: xs, y_: ys}
    sess = tf.InteractiveSession()
    # Create the MNIST neural network graph.
    # Input placeholders.
    with tf.name_scope("input"):
    x = tf.placeholder(
    tf.float32, [None, IMAGE_SIZE * IMAGE_SIZE], name="x-input")
    y_ = tf.placeholder(tf.float32, [None, NUM_LABELS], name="y-input")
    def weight_variable(shape):
    """Create a weight variable with appropriate initialization."""
    initial = tf.truncated_normal(shape, stddev=0.1, seed=RAND_SEED)
    return tf.Variable(initial)
    def bias_variable(shape):
    """Create a bias variable with appropriate initialization."""
    initial = tf.constant(0.1, shape=shape)
    return tf.Variable(initial)
    def nn_layer(input_tensor, input_dim, output_dim, layer_name, act=tf.nn.relu):
    """Reusable code for making a simple neural net layer."""
    # Adding a name scope ensures logical grouping of the layers in the graph.
    with tf.name_scope(layer_name):
    # This Variable will hold the state of the weights for the layer
    with tf.name_scope("weights"):
    weights = weight_variable([input_dim, output_dim])
    with tf.name_scope("biases"):
    biases = bias_variable([output_dim])
    with tf.name_scope("Wx_plus_b"):
    preactivate = tf.matmul(input_tensor, weights) + biases
    activations = act(preactivate)
    return activations
    hidden = nn_layer(x, IMAGE_SIZE**2, HIDDEN_SIZE, "hidden")
    logits = nn_layer(hidden, HIDDEN_SIZE, NUM_LABELS, "output", tf.identity)
    y = tf.nn.softmax(logits)
    with tf.name_scope("cross_entropy"):
    # The following line is the culprit of the bad numerical values that appear
    # during training of this graph. Log of zero gives inf, which is first seen
    # in the intermediate tensor "cross_entropy/Log:0" during the 4th run()
    # call. A multiplication of the inf values with zeros leads to nans,
    # which is first in "cross_entropy/mul:0".
    #
    # You can use the built-in, numerically-stable implementation to fix this
    # issue:
    # diff = tf.nn.softmax_cross_entropy_with_logits(labels=y_, logits=logits)
    diff = -(y_ * tf.log(y))
    with tf.name_scope("total"):
    cross_entropy = tf.reduce_mean(diff)
    with tf.name_scope("train"):
    train_step = tf.train.AdamOptimizer(FLAGS.learning_rate).minimize(
    cross_entropy)
    with tf.name_scope("accuracy"):
    with tf.name_scope("correct_prediction"):
    correct_prediction = tf.equal(tf.argmax(y, 1), tf.argmax(y_, 1))
    with tf.name_scope("accuracy"):
    accuracy = tf.reduce_mean(tf.cast(correct_prediction, tf.float32))
    sess.run(tf.global_variables_initializer())
    if FLAGS.debug:
    sess = tf_debug.LocalCLIDebugWrapperSession(sess, ui_type=FLAGS.ui_type)
    # Add this point, sess is a debug wrapper around the actual Session if
    # FLAGS.debug is true. In that case, calling run() will launch the CLI.
    for i in range(FLAGS.max_steps):
    acc = sess.run(accuracy, feed_dict=feed_dict(False))
    print("Accuracy at step %d: %s" % (i, acc))
    sess.run(train_step, feed_dict=feed_dict(True))
    if __name__ == "__main__":
    parser = argparse.ArgumentParser()
    parser.register("type", "bool", lambda v: v.lower() == "true")
    parser.add_argument(
    "--max_steps",
    type=int,
    default=10,
    help="Number of steps to run trainer.")
    parser.add_argument(
    "--train_batch_size",
    type=int,
    default=100,
    help="Batch size used during training.")
    parser.add_argument(
    "--learning_rate",
    type=float,
    default=0.025,
    help="Initial learning rate.")
    parser.add_argument(
    "--data_dir",
    type=str,
    default="/tmp/mnist_data",
    help="Directory for storing data")
    parser.add_argument(
    "--ui_type",
    type=str,
    default="curses",
    help="Command-line user interface type (curses | readline)")
    parser.add_argument(
    "--fake_data",
    type="bool",
    nargs="?",
    const=True,
    default=False,
    help="Use fake MNIST data for unit testing")
    parser.add_argument(
    "--debug",
    type="bool",
    nargs="?",
    const=True,
    default=False,
    help="Use debugger to track down bad values during training")
    FLAGS, unparsed = parser.parse_known_args()
    tf.app.run(main=main, argv=[sys.argv[0]] + unparsed)
    远程调试。tfdbg offline_analyzer。设置本地、远程机器能访问共享目录。debug_utils.watch_graph函数设置运行时参数选项。运行session.run(),中间张量、运行时图像转储到共享目录。本地终端用tfdbg offline_analyzer加载、检查共享目录数据。

    python -m tensorflow.python.debug.cli.offline_analyzer --dump_dir=/home/somebody/tfdbg_dumps_1
    源码

    from tensorflow.python.debug.lib import debug_utils
    # 构建图,生成session对象,省略
    run_options = tf.RunOptions()
    debug_utils.watch_graph(
    run_options,
    sess.graph,
    # 共享目录位置
    # 多个客户端执行run,应用多个不同共享目录
    debug_urls=["file://home/somebody/tfdbg_dumps_1"])
    session.run(fetches, feed_dict=feeds, options=run_options)
    或用会话包装器函数DumpingDebugWrapperSession在共享目录产生训练累积文件。

    from tensorflow.python.debug.lib import debug_utils
    sess = tf_debug.DumpingDebugWrapperSession(sess, "/home/somebody/tfdbg_dumps_1", watch_fn=my_watch_fn)

    参考资料:
    《TensorFlow技术解析与实战》

    欢迎推荐上海机器学习工作机会,我的微信:qingxingfengzi

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  • 原文地址:https://www.cnblogs.com/libinggen/p/7818561.html
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