Whooray, finally make AdamOptimizer work as expected.

6 years ago · bf3d1e969c
--- a/src/TensorFlowNET.Core/APIs/tf.nn.cs
+++ b/src/TensorFlowNET.Core/APIs/tf.nn.cs
@@ -3,6 +3,7 @@ using System.Collections.Generic;
 using System.Text;
 using Tensorflow.Operations;
 using Tensorflow.Operations.Activation;
 using static Tensorflow.Python;
 namespace Tensorflow
 {
@@ -101,6 +102,25 @@ namespace Tensorflow
            Tensor logits = null, string name = null)
                => nn_ops.sparse_softmax_cross_entropy_with_logits(labels: labels, logits: logits, name: name);
            /// <summary>
            /// Computes softmax cross entropy between `logits` and `labels`.
            /// </summary>
            /// <param name="labels"></param>
            /// <param name="logits"></param>
            /// <param name="dim"></param>
            /// <param name="name"></param>
            /// <returns></returns>
            public static Tensor softmax_cross_entropy_with_logits(Tensor labels, Tensor logits, int dim = -1, string name = null)
            {
                with(ops.name_scope(name, "softmax_cross_entropy_with_logits_sg", new { logits, labels }), scope =>
                {
                    name = scope;
                    labels = array_ops.stop_gradient(labels, name: "labels_stop_gradient");
                });
                return softmax_cross_entropy_with_logits_v2(labels, logits, axis: dim, name: name);
            }
            public static Tensor softmax_cross_entropy_with_logits_v2(Tensor labels, Tensor logits, int axis = -1, string name = null)
                => nn_ops.softmax_cross_entropy_with_logits_v2_helper(labels, logits, axis: axis, name: name);
        }
--- a/src/TensorFlowNET.Core/Operations/OpDefLibrary.cs
+++ b/src/TensorFlowNET.Core/Operations/OpDefLibrary.cs
@@ -94,14 +94,28 @@ namespace Tensorflow
                            if (attrs.ContainsKey(input_arg.TypeAttr))
                                dtype = (DataType)attrs[input_arg.TypeAttr];
                            else
                                if (values is Tensor[] values1)
                                    dtype = values1[0].dtype.as_datatype_enum();
                                switch (values)
                                {
                                    case Tensor[] values1:
                                        dtype = values1[0].dtype.as_datatype_enum();
                                        break;
                                    case object[] values1:
                                        foreach(var t in values1)
                                            if(t is Tensor tensor)
                                            {
                                                dtype = tensor.dtype.as_datatype_enum();
                                                break;
                                            }
                                        break;
                                    default:
                                        throw new NotImplementedException($"can't infer the dtype for {values.GetType()}");
                                }
                            if (dtype == DataType.DtInvalid && default_type_attr_map.ContainsKey(input_arg.TypeAttr))
                                default_dtype = (DataType)default_type_attr_map[input_arg.TypeAttr];
                        }
                        if(input_arg.IsRef && dtype != DataType.DtInvalid)
                        if(!input_arg.IsRef && dtype != DataType.DtInvalid)
                            dtype = dtype.as_base_dtype();
                        values = ops.internal_convert_n_to_tensor(values, 
--- a/src/TensorFlowNET.Core/Operations/Operation.Output.cs
+++ b/src/TensorFlowNET.Core/Operations/Operation.Output.cs
@@ -17,9 +17,7 @@ namespace Tensorflow
        private Tensor[] _outputs;
        public Tensor[] outputs => _outputs;
 #if GRAPH_SERIALIZE
        [JsonIgnore]
 #endif
        public Tensor output => _outputs.FirstOrDefault();
        public int NumControlOutputs => c_api.TF_OperationNumControlOutputs(_handle);
--- a/src/TensorFlowNET.Core/Operations/Operation.cs
+++ b/src/TensorFlowNET.Core/Operations/Operation.cs
@@ -1,7 +1,4 @@
 using Google.Protobuf.Collections;
 #if GRAPH_SERIALIZE
 using Newtonsoft.Json;
 #endif
 using System;
 using System.Collections.Generic;
 using System.Linq;
@@ -37,21 +34,11 @@ namespace Tensorflow
        private Graph _graph;
        public string type => OpType;
 #if GRAPH_SERIALIZE
        [JsonIgnore]
        public Graph graph => _graph;
        [JsonIgnore]
        public int _id => _id_value;
        [JsonIgnore]
        public int _id_value;
        [JsonIgnore]
        public Operation op => this;
 #else
        public Graph graph => _graph;
        public int _id => _id_value;
        public int _id_value;
        public Operation op => this;
 #endif
        public TF_DataType dtype => TF_DataType.DtInvalid;
        private Status status = new Status();
@@ -60,9 +47,6 @@ namespace Tensorflow
        public string Device => c_api.StringPiece(c_api.TF_OperationDevice(_handle));
        private NodeDef _node_def;
 #if GRAPH_SERIALIZE
        [JsonIgnore]
 #endif
        public NodeDef node_def
        {
            get
--- a/src/TensorFlowNET.Core/Operations/array_ops.py.cs
+++ b/src/TensorFlowNET.Core/Operations/array_ops.py.cs
@@ -492,13 +492,18 @@ namespace Tensorflow
            {
                return with(ops.name_scope(name), scope => {
                    var t = ops.convert_to_tensor(axis, name: "concat_dim", dtype: TF_DataType.TF_INT32);
                    return identity(values[0], name = scope);
                    return identity(values[0], name: scope);
                });
            }
            return gen_array_ops.concat_v2(values, axis, name: name);
        }
        public static Tensor concat(object[] values, int axis, string name = "concat")
        {
            return gen_array_ops.concat_v2(values, axis, name: name);
        }
        public static Tensor gather(Tensor @params, Tensor indices, string name = null, int axis = 0)
            => gen_array_ops.gather_v2(@params, indices, axis, name: name);
--- a/src/TensorFlowNET.Core/Operations/gen_array_ops.cs
+++ b/src/TensorFlowNET.Core/Operations/gen_array_ops.cs
@@ -19,7 +19,7 @@ namespace Tensorflow
        /// <param name="axis"></param>
        /// <param name="name"></param>
        /// <returns></returns>
        public static Tensor concat_v2(Tensor[] values, int axis, string name = null)
        public static Tensor concat_v2<T>(T[] values, int axis, string name = null)
        {
            var _op = _op_def_lib._apply_op_helper("ConcatV2", name: name, args: new { values, axis });
--- a/src/TensorFlowNET.Core/Operations/nn_ops.cs
+++ b/src/TensorFlowNET.Core/Operations/nn_ops.cs
@@ -1,5 +1,6 @@
 using System;
 using System.Collections.Generic;
 using System.Linq;
 using System.Text;
 using Tensorflow.Operations;
 using static Tensorflow.Python;
@@ -159,8 +160,9 @@ namespace Tensorflow
            int axis = -1,
            string name = null)
        {
            return Python.with(ops.name_scope(name, "softmax_cross_entropy_with_logits", new { }), scope =>
            return with(ops.name_scope(name, "softmax_cross_entropy_with_logits", new { logits, labels }), scope =>
            {
                name = scope;
                var precise_logits = logits;
                var input_rank = array_ops.rank(precise_logits);
                var shape = logits.TensorShape;
@@ -170,6 +172,10 @@ namespace Tensorflow
                var input_shape = array_ops.shape(precise_logits);
                // Make precise_logits and labels into matrices.
                precise_logits = _flatten_outer_dims(precise_logits);
                labels = _flatten_outer_dims(labels);
                // Do the actual op computation.
                // The second output tensor contains the gradients.  We use it in
                // _CrossEntropyGrad() in nn_grad but not here.
@@ -186,5 +192,50 @@ namespace Tensorflow
                return cost;
            });
        }
        /// <summary>
        /// Flattens logits' outer dimensions and keep its last dimension.
        /// </summary>
        /// <param name="logits"></param>
        /// <returns></returns>
        private static Tensor _flatten_outer_dims(Tensor logits)
        {
            var rank = array_ops.rank(logits);
            var last_dim_size = array_ops.slice(array_ops.shape(logits),
                new[] { math_ops.subtract(rank, 1) },
                new[] { 1 });
            var ops = array_ops.concat(new[] { new[] { -1 }, (object)last_dim_size }, 0);
            var output = array_ops.reshape(logits, ops);
            // Set output shape if known.
            // if not context.executing_eagerly():
            var shape = logits.TensorShape;
            if(shape != null && shape.NDim > 0)
            {
                var product = 1;
                var product_valid = true;
                foreach(var d in shape.Dimensions.Take(shape.NDim - 1))
                {
                    if(d == -1)
                    {
                        product_valid = false;
                        break;
                    }
                    else
                    {
                        product *= d;
                    }
                }
                if (product_valid)
                {
                    var output_shape = new[] { product };
                    throw new NotImplementedException("_flatten_outer_dims product_valid");
                }
            }
            return output;
        }
    }
 }
--- a/src/TensorFlowNET.Core/Tensors/Tensor.cs
+++ b/src/TensorFlowNET.Core/Tensors/Tensor.cs
@@ -22,21 +22,11 @@ namespace Tensorflow
        private int _id;
        private Operation _op;
 #if GRAPH_SERIALIZE
        [JsonIgnore]
        public int Id => _id;
        [JsonIgnore]
        public Graph graph => op?.graph;
        [JsonIgnore]
        public Operation op => _op;
        [JsonIgnore]
        public Tensor[] outputs => op.outputs;
 #else
        public int Id => _id;
        public Graph graph => op?.graph;
        public Operation op => _op;
        public Tensor[] outputs => op.outputs;
 #endif
        /// <summary>
        /// The string name of this tensor.
@@ -50,18 +40,12 @@ namespace Tensorflow
        private TF_DataType _dtype = TF_DataType.DtInvalid;
        public TF_DataType dtype => _handle == IntPtr.Zero ? _dtype : c_api.TF_TensorType(_handle);
 #if GRAPH_SERIALIZE
        [JsonIgnore]
 #endif
        public ulong bytesize => _handle == IntPtr.Zero ? 0 : c_api.TF_TensorByteSize(_handle);
 #if GRAPH_SERIALIZE
        [JsonIgnore]
 #endif
        public ulong itemsize => _handle == IntPtr.Zero ? 0 : c_api.TF_DataTypeSize(dtype);
        public ulong size => _handle == IntPtr.Zero ? 0 : bytesize / itemsize;
 #if GRAPH_SERIALIZE
        [JsonIgnore]
 #endif
        public IntPtr buffer => _handle == IntPtr.Zero ? IntPtr.Zero : c_api.TF_TensorData(_handle);
        public int num_consumers(TF_Output oper_out) => _handle == IntPtr.Zero ? 0 : c_api.TF_OperationOutputNumConsumers(oper_out);
@@ -70,9 +54,6 @@ namespace Tensorflow
        /// <summary>
        /// used for keep other pointer when do implicit operating
        /// </summary>
 #if GRAPH_SERIALIZE
        [JsonIgnore]
 #endif
        public object Tag { get; set; }
        public int[] shape
@@ -140,9 +121,7 @@ namespace Tensorflow
                }
            }
        }
 #if GRAPH_SERIALIZE
        [JsonIgnore]
 #endif
        public int NDims => rank;
        public string Device => op.Device;
--- a/src/TensorFlowNET.Core/Train/AdamOptimizer.cs
+++ b/src/TensorFlowNET.Core/Train/AdamOptimizer.cs
@@ -110,7 +110,7 @@ namespace Tensorflow.Train
                var update_beta2 = beta2_power.assign(beta2_power * _beta2_t, use_locking: _use_locking);
                operations.Add(update_beta1);
                operations.Add(update_beta1);
                operations.Add(update_beta2);
            });
            return control_flow_ops.group(operations.ToArray(), name: name_scope);
--- a/test/TensorFlowNET.Examples/ImageProcess/DigitRecognitionNN.cs
+++ b/test/TensorFlowNET.Examples/ImageProcess/DigitRecognitionNN.cs
@@ -49,8 +49,6 @@ namespace TensorFlowNET.Examples.ImageProcess
        public Graph BuildGraph()
        {
            var g = tf.Graph();
            // Placeholders for inputs (x) and outputs(y)
            x = tf.placeholder(tf.float32, shape: (-1, img_size_flat), name: "X");
            y = tf.placeholder(tf.float32, shape: (-1, n_classes), name: "Y");
@@ -60,7 +58,8 @@ namespace TensorFlowNET.Examples.ImageProcess
            // Create a fully-connected layer with n_classes nodes as output layer
            var output_logits = fc_layer(fc1, n_classes, "OUT", use_relu: false);
            // Define the loss function, optimizer, and accuracy
            loss = tf.reduce_mean(tf.nn.softmax_cross_entropy_with_logits_v2(labels: y, logits: output_logits), name: "loss");
            var logits = tf.nn.softmax_cross_entropy_with_logits(labels: y, logits: output_logits);
            loss = tf.reduce_mean(logits, name: "loss");
            optimizer = tf.train.AdamOptimizer(learning_rate: learning_rate, name: "Adam-op").minimize(loss);
            var correct_prediction = tf.equal(tf.argmax(output_logits, 1), tf.argmax(y, 1), name: "correct_pred");
            accuracy = tf.reduce_mean(tf.cast(correct_prediction, tf.float32), name: "accuracy");
@@ -68,7 +67,7 @@ namespace TensorFlowNET.Examples.ImageProcess
            // Network predictions
            var cls_prediction = tf.argmax(output_logits, axis: 1, name: "predictions");
            return g;
            return tf.get_default_graph();
        }
        private Tensor fc_layer(Tensor x, int num_units, string name, bool use_relu = true)
@@ -93,16 +92,10 @@ namespace TensorFlowNET.Examples.ImageProcess
            return layer;
        } 
        public Graph ImportGraph()
        {
            throw new NotImplementedException();
        }
        public bool Predict()
        {
            throw new NotImplementedException();
        }
        public Graph ImportGraph() => throw new NotImplementedException();
        public bool Predict() => throw new NotImplementedException();
        public void PrepareData()
        {
            mnist = MnistDataSet.read_data_sets("mnist", one_hot: true);
@@ -112,7 +105,6 @@ namespace TensorFlowNET.Examples.ImageProcess
        {
            // Number of training iterations in each epoch
            var num_tr_iter = mnist.train.labels.len / batch_size;
            return with(tf.Session(), sess =>
            {
                var init = tf.global_variables_initializer();
@@ -153,10 +145,9 @@ namespace TensorFlowNET.Examples.ImageProcess
                    print("---------------------------------------------------------");
                    print($"Epoch: {epoch + 1}, validation loss: {loss_val.ToString("0.0000")}, validation accuracy: {accuracy_val.ToString("P")}");
                    print("---------------------------------------------------------");
                }
                return accuracy_val > 0.9;
                return accuracy_val > 0.95;
            });
        }
--- a/test/TensorFlowNET.Examples/python/neural_network.py
+++ b/test/TensorFlowNET.Examples/python/neural_network.py
@@ -0,0 +1,164 @@
 # imports
 import tensorflow as tf
 import numpy as np
 import matplotlib.pyplot as plt
 img_h = img_w = 28             # MNIST images are 28x28
 img_size_flat = img_h * img_w  # 28x28=784, the total number of pixels
 n_classes = 10                 # Number of classes, one class per digit
 def load_data(mode='train'):
    """
    Function to (download and) load the MNIST data
    :param mode: train or test
    :return: images and the corresponding labels
    """
    from tensorflow.examples.tutorials.mnist import input_data
    mnist = input_data.read_data_sets("MNIST_data/", one_hot=True)
    if mode == 'train':
        x_train, y_train, x_valid, y_valid = mnist.train.images, mnist.train.labels, \
                                             mnist.validation.images, mnist.validation.labels
        return x_train, y_train, x_valid, y_valid
    elif mode == 'test':
        x_test, y_test = mnist.test.images, mnist.test.labels
    return x_test, y_test
 def randomize(x, y):
    """ Randomizes the order of data samples and their corresponding labels"""
    permutation = np.random.permutation(y.shape[0])
    shuffled_x = x[permutation, :]
    shuffled_y = y[permutation]
    return shuffled_x, shuffled_y
 def get_next_batch(x, y, start, end):
    x_batch = x[start:end]
    y_batch = y[start:end]
    return x_batch, y_batch
 # Load MNIST data
 x_train, y_train, x_valid, y_valid = load_data(mode='train')
 print("Size of:")
 print("- Training-set:\t\t{}".format(len(y_train)))
 print("- Validation-set:\t{}".format(len(y_valid)))
 print('x_train:\t{}'.format(x_train.shape))
 print('y_train:\t{}'.format(y_train.shape))
 print('x_train:\t{}'.format(x_valid.shape))
 print('y_valid:\t{}'.format(y_valid.shape))
 print(y_valid[:5, :])
 # Hyper-parameters
 epochs = 10             # Total number of training epochs
 batch_size = 100        # Training batch size
 display_freq = 100      # Frequency of displaying the training results
 learning_rate = 0.001   # The optimization initial learning rate
 h1 = 200                # number of nodes in the 1st hidden layer
 # weight and bais wrappers
 def weight_variable(name, shape):
    """
    Create a weight variable with appropriate initialization
    :param name: weight name
    :param shape: weight shape
    :return: initialized weight variable
    """
    initer = tf.truncated_normal_initializer(stddev=0.01)
    return tf.get_variable('W_' + name,
                           dtype=tf.float32,
                           shape=shape,
                           initializer=initer)
 def bias_variable(name, shape):
    """
    Create a bias variable with appropriate initialization
    :param name: bias variable name
    :param shape: bias variable shape
    :return: initialized bias variable
    """
    initial = tf.constant(0., shape=shape, dtype=tf.float32)
    return tf.get_variable('b_' + name,
                           dtype=tf.float32,
                           initializer=initial)
 def fc_layer(x, num_units, name, use_relu=True):
    """
    Create a fully-connected layer
    :param x: input from previous layer
    :param num_units: number of hidden units in the fully-connected layer
    :param name: layer name
    :param use_relu: boolean to add ReLU non-linearity (or not)
    :return: The output array
    """
    in_dim = x.get_shape()[1]
    W = weight_variable(name, shape=[in_dim, num_units])
    b = bias_variable(name, [num_units])
    layer = tf.matmul(x, W)
    layer += b
    if use_relu:
        layer = tf.nn.relu(layer)
    return layer
 # Create the graph for the linear model
 # Placeholders for inputs (x) and outputs(y)
 x = tf.placeholder(tf.float32, shape=[None, img_size_flat], name='X')
 y = tf.placeholder(tf.float32, shape=[None, n_classes], name='Y')
 # Create a fully-connected layer with h1 nodes as hidden layer
 fc1 = fc_layer(x, h1, 'FC1', use_relu=True)
 # Create a fully-connected layer with n_classes nodes as output layer
 output_logits = fc_layer(fc1, n_classes, 'OUT', use_relu=False)
 # Define the loss function, optimizer, and accuracy
 logits = tf.nn.softmax_cross_entropy_with_logits(labels=y, logits=output_logits)
 loss = tf.reduce_mean(logits, name='loss')
 optimizer = tf.train.AdamOptimizer(learning_rate=learning_rate, name='Adam-op').minimize(loss)
 correct_prediction = tf.equal(tf.argmax(output_logits, 1), tf.argmax(y, 1), name='correct_pred')
 accuracy = tf.reduce_mean(tf.cast(correct_prediction, tf.float32), name='accuracy')
 # Network predictions
 cls_prediction = tf.argmax(output_logits, axis=1, name='predictions')
 # export graph
 #tf.train.export_meta_graph(filename='neural_network.meta', graph=tf.get_default_graph(), clear_extraneous_savers= True, as_text = True)
 # Create the op for initializing all variables
 init = tf.global_variables_initializer()
 # Create an interactive session (to keep the session in the other cells)
 sess = tf.InteractiveSession()
 # Initialize all variables
 sess.run(init)
 # Number of training iterations in each epoch
 num_tr_iter = int(len(y_train) / batch_size)
 for epoch in range(epochs):
    print('Training epoch: {}'.format(epoch + 1))
    # Randomly shuffle the training data at the beginning of each epoch 
    x_train, y_train = randomize(x_train, y_train)
    for iteration in range(num_tr_iter):
        start = iteration * batch_size
        end = (iteration + 1) * batch_size
        x_batch, y_batch = get_next_batch(x_train, y_train, start, end)
        # Run optimization op (backprop)
        feed_dict_batch = {x: x_batch, y: y_batch}
        sess.run(optimizer, feed_dict=feed_dict_batch)
        if iteration % display_freq == 0:
            # Calculate and display the batch loss and accuracy
            loss_batch, acc_batch = sess.run([loss, accuracy],
                                             feed_dict=feed_dict_batch)
            print("iter {0:3d}:\t Loss={1:.2f},\tTraining Accuracy={2:.01%}".
                  format(iteration, loss_batch, acc_batch))
    # Run validation after every epoch
    feed_dict_valid = {x: x_valid[:1000], y: y_valid[:1000]}
    loss_valid, acc_valid = sess.run([loss, accuracy], feed_dict=feed_dict_valid)
    print('---------------------------------------------------------')
    print("Epoch: {0}, validation loss: {1:.2f}, validation accuracy: {2:.01%}".
          format(epoch + 1, loss_valid, acc_valid))
    print('---------------------------------------------------------')