• tensorflow 的 tutorial 的卷积神经网络的例子 convolutional.py


    具体的网址在这里:

    https://github.com/tensorflow/tensorflow/tree/r0.12/tensorflow/models

    一个卷积神经网络用于股票分析的例子:  https://github.com/keon/deepstock,      https://github.com/keon/deepstock

    import argparse
    import gzip
    import os
    import sys
    import time
    
    import numpy
    import tensorflow as tf
    
    SOURCE_URL = 'http://yann.lecun.com/exdb/mnist/'
    WORK_DIRECTORY = '/home/hzh/tf'
    IMAGE_SIZE = 28
    NUM_CHANNELS = 1
    PIXEL_DEPTH = 255
    NUM_LABELS = 10
    VALIDATION_SIZE = 5000  # Size of the validation set.
    SEED = 66478  # Set to None for random seed.
    BATCH_SIZE = 64
    NUM_EPOCHS = 10
    EVAL_BATCH_SIZE = 64
    EVAL_FREQUENCY = 100  # Number of steps between evaluations.
    
    
    FLAGS = None
    
    
    def data_type():
        """Return the type of the activations, weights, and placeholder variables."""
        if FLAGS.use_fp16:
            return tf.float16
        else:
            return tf.float32
    
    
    def maybe_download(filename):
        """Download the data from Yann's website, unless it's already here."""
        if not tf.gfile.Exists(WORK_DIRECTORY):
            tf.gfile.MakeDirs(WORK_DIRECTORY)
        filepath = os.path.join(WORK_DIRECTORY, filename)
        return filepath
    
    
    def extract_data(filename, num_images):
        """Extract the images into a 4D tensor [image index, y, x, channels].
        Values are rescaled from [0, 255] down to [-0.5, 0.5].
        """
        print('Extracting', filename)
        with gzip.open(filename) as bytestream:
            bytestream.read(16)
            buf = bytestream.read(IMAGE_SIZE * IMAGE_SIZE * num_images * NUM_CHANNELS)
            data = numpy.frombuffer(buf, dtype=numpy.uint8).astype(numpy.float32)
            data = (data - (PIXEL_DEPTH / 2.0)) / PIXEL_DEPTH
            data = data.reshape(num_images, IMAGE_SIZE, IMAGE_SIZE, NUM_CHANNELS)
            return data
    
    
    def extract_labels(filename, num_images):
        """Extract the labels into a vector of int64 label IDs."""
        print('Extracting', filename)
        with gzip.open(filename) as bytestream:
            bytestream.read(8)
            buf = bytestream.read(1 * num_images)
            labels = numpy.frombuffer(buf, dtype=numpy.uint8).astype(numpy.int64)
        return labels
    
    
    def fake_data(num_images):
        """Generate a fake dataset that matches the dimensions of MNIST."""
        data = numpy.ndarray(
            shape=(num_images, IMAGE_SIZE, IMAGE_SIZE, NUM_CHANNELS),
            dtype=numpy.float32)
        labels = numpy.zeros(shape=(num_images,), dtype=numpy.int64)
        for image in range(num_images):
            label = image % 2
            data[image, :, :, 0] = label - 0.5
            labels[image] = label
        return data, labels
    
    
    def error_rate(predictions, labels):
        """Return the error rate based on dense predictions and sparse labels."""
        return 100.0 - (
            100.0 *
            numpy.sum(numpy.argmax(predictions, 1) == labels) / predictions.shape[0])
    
    
    def main(_):
        if FLAGS.self_test:
            print('Running self-test.')
            train_data, train_labels = fake_data(256)
            validation_data, validation_labels = fake_data(EVAL_BATCH_SIZE)
            test_data, test_labels = fake_data(EVAL_BATCH_SIZE)
            num_epochs = 1
        else:
            # Get the data.
            train_data_filename = maybe_download('train-images-idx3-ubyte.gz')
            train_labels_filename = maybe_download('train-labels-idx1-ubyte.gz')
            test_data_filename = maybe_download('t10k-images-idx3-ubyte.gz')
            test_labels_filename = maybe_download('t10k-labels-idx1-ubyte.gz')
    
            # Extract it into numpy arrays.
            train_data = extract_data(train_data_filename, 60000)
            train_labels = extract_labels(train_labels_filename, 60000)
            test_data = extract_data(test_data_filename, 10000)
            test_labels = extract_labels(test_labels_filename, 10000)
    
            # Generate a validation set.
            validation_data = train_data[:VALIDATION_SIZE, ...]
            validation_labels = train_labels[:VALIDATION_SIZE]
            train_data = train_data[VALIDATION_SIZE:, ...]
            train_labels = train_labels[VALIDATION_SIZE:]
            num_epochs = NUM_EPOCHS
        train_size = train_labels.shape[0]
    
        # This is where training samples and labels are fed to the graph.
        # These placeholder nodes will be fed a batch of training data at each
        # training step using the {feed_dict} argument to the Run() call below.
        train_data_node = tf.placeholder(
            data_type(),
            shape=(BATCH_SIZE, IMAGE_SIZE, IMAGE_SIZE, NUM_CHANNELS))
        train_labels_node = tf.placeholder(tf.int64, shape=(BATCH_SIZE,))
        eval_data = tf.placeholder(
            data_type(),
            shape=(EVAL_BATCH_SIZE, IMAGE_SIZE, IMAGE_SIZE, NUM_CHANNELS))
    
        # The variables below hold all the trainable weights. They are passed an
        # initial value which will be assigned when we call:
        # {tf.global_variables_initializer().run()}
        conv1_weights = tf.Variable(
            tf.truncated_normal([5, 5, NUM_CHANNELS, 32],  # 5x5 filter, depth 32.
                                stddev=0.1,
                                seed=SEED, dtype=data_type()))
        conv1_biases = tf.Variable(tf.zeros([32], dtype=data_type()))
        conv2_weights = tf.Variable(tf.truncated_normal(
            [5, 5, 32, 64], stddev=0.1,
            seed=SEED, dtype=data_type()))
        conv2_biases = tf.Variable(tf.constant(0.1, shape=[64], dtype=data_type()))
        fc1_weights = tf.Variable(  # fully connected, depth 512.
            tf.truncated_normal([IMAGE_SIZE // 4 * IMAGE_SIZE // 4 * 64, 512],
                                stddev=0.1,
                                seed=SEED,
                                dtype=data_type()))
        fc1_biases = tf.Variable(tf.constant(0.1, shape=[512], dtype=data_type()))
        fc2_weights = tf.Variable(tf.truncated_normal([512, NUM_LABELS],
                                                      stddev=0.1,
                                                      seed=SEED,
                                                      dtype=data_type()))
        fc2_biases = tf.Variable(tf.constant(0.1, shape=[NUM_LABELS], dtype=data_type()))
    
        # We will replicate the model structure for the training subgraph, as well
        # as the evaluation subgraphs, while sharing the trainable parameters.
        def model(data, train=False):
            """The Model definition."""
            # 2D convolution, with 'SAME' padding (i.e. the output feature map has
            # the same size as the input). Note that {strides} is a 4D array whose
            # shape matches the data layout: [image index, y, x, depth].
            conv = tf.nn.conv2d(data,
                                conv1_weights,
                                strides=[1, 1, 1, 1],
                                padding='SAME')
            # Bias and rectified linear non-linearity.
            relu = tf.nn.relu(tf.nn.bias_add(conv, conv1_biases))
            # Max pooling. The kernel size spec {ksize} also follows the layout of
            # the data. Here we have a pooling window of 2, and a stride of 2.
            pool = tf.nn.max_pool(relu,
                                  ksize=[1, 2, 2, 1],
                                  strides=[1, 2, 2, 1],
                                  padding='SAME')
            conv = tf.nn.conv2d(pool,
                                conv2_weights,
                                strides=[1, 1, 1, 1],
                                padding='SAME')
            relu = tf.nn.relu(tf.nn.bias_add(conv, conv2_biases))
            pool = tf.nn.max_pool(relu,
                                  ksize=[1, 2, 2, 1],
                                  strides=[1, 2, 2, 1],
                                  padding='SAME')
            # Reshape the feature map cuboid into a 2D matrix to feed it to the
            # fully connected layers.
            pool_shape = pool.get_shape().as_list()
            reshape = tf.reshape(
                pool,
                [pool_shape[0], pool_shape[1] * pool_shape[2] * pool_shape[3]])
            # Fully connected layer. Note that the '+' operation automatically
            # broadcasts the biases.
            hidden = tf.nn.relu(tf.matmul(reshape, fc1_weights) + fc1_biases)
            # Add a 50% dropout during training only. Dropout also scales
            # activations such that no rescaling is needed at evaluation time.
            if train:
                hidden = tf.nn.dropout(hidden, 0.5, seed=SEED)
            return tf.matmul(hidden, fc2_weights) + fc2_biases
    
        # Training computation: logits + cross-entropy loss.
        logits = model(train_data_node, True)
        loss = tf.reduce_mean(tf.nn.sparse_softmax_cross_entropy_with_logits(logits=logits, labels=train_labels_node))
    
        # L2 regularization for the fully connected parameters.
        regularizers = (tf.nn.l2_loss(fc1_weights) + tf.nn.l2_loss(fc1_biases) +
                        tf.nn.l2_loss(fc2_weights) + tf.nn.l2_loss(fc2_biases))
        # Add the regularization term to the loss.
        loss += 5e-4 * regularizers
    
        # Optimizer: set up a variable that's incremented once per batch and
        # controls the learning rate decay.
        batch = tf.Variable(0, dtype=data_type())
        # Decay once per epoch, using an exponential schedule starting at 0.01.
        learning_rate = tf.train.exponential_decay(
            0.01,                # Base learning rate.
            batch * BATCH_SIZE,  # Current index into the dataset.
            train_size,          # Decay step.
            0.95,                # Decay rate.
            staircase=True)
        # Use simple momentum for the optimization.
        optimizer = tf.train.MomentumOptimizer(learning_rate,
                                               0.9).minimize(loss,
                                                             global_step=batch)
    
        # Predictions for the current training minibatch.
        train_prediction = tf.nn.softmax(logits)
    
        # Predictions for the test and validation, which we'll compute less often.
        eval_prediction = tf.nn.softmax(model(eval_data))
    
        # Small utility function to evaluate a dataset by feeding batches of data to
        # {eval_data} and pulling the results from {eval_predictions}.
        # Saves memory and enables this to run on smaller GPUs.
        def eval_in_batches(data, sess):
            """Get all predictions for a dataset by running it in small batches."""
            size = data.shape[0]
            if size < EVAL_BATCH_SIZE:
                raise ValueError("batch size for evals larger than dataset: %d" % size)
            predictions = numpy.ndarray(shape=(size, NUM_LABELS), dtype=numpy.float32)
            for begin in range(0, size, EVAL_BATCH_SIZE):
                end = begin + EVAL_BATCH_SIZE
                if end <= size:
                    predictions[begin:end, :] = sess.run(
                        eval_prediction,
                        feed_dict={eval_data: data[begin:end, ...]})
                else:
                    batch_predictions = sess.run(
                        eval_prediction,
                        feed_dict={eval_data: data[-EVAL_BATCH_SIZE:, ...]})
                    predictions[begin:, :] = batch_predictions[begin - size:, :]
            return predictions
    
        # Create a local session to run the training.
        start_time = time.time()
        with tf.Session() as sess:
            # Run all the initializers to prepare the trainable parameters.
            tf.global_variables_initializer().run()
            print('Initialized!')
            # Loop through training steps.
            for step in range(int(num_epochs * train_size) // BATCH_SIZE):
                # Compute the offset of the current minibatch in the data.
                # Note that we could use better randomization across epochs.
                offset = (step * BATCH_SIZE) % (train_size - BATCH_SIZE)
                batch_data = train_data[offset:(offset + BATCH_SIZE), ...]
                batch_labels = train_labels[offset:(offset + BATCH_SIZE)]
                # This dictionary maps the batch data (as a numpy array) to the
                # node in the graph it should be fed to.
                feed_dict = {train_data_node: batch_data, train_labels_node: batch_labels}
                # Run the optimizer to update weights.
                sess.run(optimizer, feed_dict=feed_dict)
                # print some extra information once reach the evaluation frequency
                if step % EVAL_FREQUENCY == 0:
                    # fetch some extra nodes' data
                    l, lr, predictions = sess.run([loss, learning_rate, train_prediction], feed_dict=feed_dict)
                    elapsed_time = time.time() - start_time
                    start_time = time.time()
                    print('Step %d (epoch %.2f), %.1f ms' %
                          (step, float(step) * BATCH_SIZE / train_size,
                           1000 * elapsed_time / EVAL_FREQUENCY))
                    print('Minibatch loss: %.3f, learning rate: %.6f' % (l, lr))
                    print('Minibatch error: %.1f%%' % error_rate(predictions, batch_labels))
                    print('Validation error: %.1f%%' % error_rate(eval_in_batches(validation_data, sess), validation_labels))
                    sys.stdout.flush()
            # Finally print the result!
            test_error = error_rate(eval_in_batches(test_data, sess), test_labels)
            print('Test error: %.1f%%' % test_error)
            if FLAGS.self_test:
                print('test_error', test_error)
                assert test_error == 0.0, 'expected 0.0 test_error, got %.2f' % (test_error,)
    
    
    if __name__ == '__main__':
        parser = argparse.ArgumentParser()
        parser.add_argument(
            '--use_fp16',
            default=False,
            help='Use half floats instead of full floats if True.',
            action='store_true')
        parser.add_argument(
            '--self_test',
            default=False,
            action='store_true',
            help='True if running a self test.')
    
        FLAGS, unparsed = parser.parse_known_args()
        tf.app.run(main=main, argv=[sys.argv[0]] + unparsed)

    网址里面还有很多其它的示例,这些示例代码是最全的,比google网站上的还全,也比 github 上最新的 tensorflow 的库的例子要全要好 。

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  • 原文地址:https://www.cnblogs.com/welhzh/p/6649154.html
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