Merge branch 'master' into tf.keras-0.3.image-classification

5 years ago · 8b6dc478b2
--- a/README.md
+++ b/README.md
@@ -56,30 +56,32 @@ PM> Install-Package SciSharp.TensorFlow.Redist-Windows-GPU
 Import TF.NET and Keras API in your project.
 ```cs
 ```csharp
 using static Tensorflow.Binding;
 using static Tensorflow.KerasApi;
 using Tensorflow;
 using NumSharp;
 ```
 Linear Regression in `Eager` mode:
 ```c#
 ```csharp
 // Parameters        
 var training_steps = 1000;
 var learning_rate = 0.01f;
 var display_step = 100;
 // Sample data
 var train_X = np.array(3.3f, 4.4f, 5.5f, 6.71f, 6.93f, 4.168f, 9.779f, 6.182f, 7.59f, 2.167f,
 var X = np.array(3.3f, 4.4f, 5.5f, 6.71f, 6.93f, 4.168f, 9.779f, 6.182f, 7.59f, 2.167f,
             7.042f, 10.791f, 5.313f, 7.997f, 5.654f, 9.27f, 3.1f);
 var train_Y = np.array(1.7f, 2.76f, 2.09f, 3.19f, 1.694f, 1.573f, 3.366f, 2.596f, 2.53f, 1.221f,
 var Y = np.array(1.7f, 2.76f, 2.09f, 3.19f, 1.694f, 1.573f, 3.366f, 2.596f, 2.53f, 1.221f,
             2.827f, 3.465f, 1.65f, 2.904f, 2.42f, 2.94f, 1.3f);
 var n_samples = train_X.shape[0];
 var n_samples = X.shape[0];
 // We can set a fixed init value in order to demo
 var W = tf.Variable(-0.06f, name: "weight");
 var b = tf.Variable(-0.73f, name: "bias");
 var optimizer = tf.optimizers.SGD(learning_rate);
 var optimizer = keras.optimizers.SGD(learning_rate);
 // Run training for the given number of steps.
 foreach (var step in range(1, training_steps + 1))
@@ -112,46 +114,40 @@ Run this example in [Jupyter Notebook](https://github.com/SciSharp/SciSharpCube)
 Toy version of `ResNet` in `Keras` functional API:
 ```csharp
 var layers = new LayersApi();
 // input layer
 var inputs = keras.Input(shape: (32, 32, 3), name: "img");
 // convolutional layer
 var x = layers.Conv2D(32, 3, activation: "relu").Apply(inputs);
 x = layers.Conv2D(64, 3, activation: "relu").Apply(x);
 var block_1_output = layers.MaxPooling2D(3).Apply(x);
 x = layers.Conv2D(64, 3, activation: "relu", padding: "same").Apply(block_1_output);
 x = layers.Conv2D(64, 3, activation: "relu", padding: "same").Apply(x);
 var block_2_output = layers.add(x, block_1_output);
 var block_2_output = layers.Add().Apply(new Tensors(x, block_1_output));
 x = layers.Conv2D(64, 3, activation: "relu", padding: "same").Apply(block_2_output);
 x = layers.Conv2D(64, 3, activation: "relu", padding: "same").Apply(x);
 var block_3_output = layers.add(x, block_2_output);
 var block_3_output = layers.Add().Apply(new Tensors(x, block_2_output));
 x = layers.Conv2D(64, 3, activation: "relu").Apply(block_3_output);
 x = layers.GlobalAveragePooling2D().Apply(x);
 x = layers.Dense(256, activation: "relu").Apply(x);
 x = layers.Dropout(0.5f).Apply(x);
 // output layer
 var outputs = layers.Dense(10).Apply(x);
 // build keras model
 model = keras.Model(inputs, outputs, name: "toy_resnet");
 var model = keras.Model(inputs, outputs, name: "toy_resnet");
 model.summary();
 // compile keras model in tensorflow static graph
 model.compile(optimizer: keras.optimizers.RMSprop(1e-3f),
 	loss: keras.losses.CategoricalCrossentropy(from_logits: true),
 	metrics: new[] { "acc" });
    loss: keras.losses.CategoricalCrossentropy(from_logits: true),
    metrics: new[] { "acc" });
 // prepare dataset
 var ((x_train, y_train), (x_test, y_test)) = keras.datasets.cifar10.load_data();
 x_train = x_train / 255.0f;
 y_train = np_utils.to_categorical(y_train, 10);
 // training
 model.fit(x_train[new Slice(0, 1000)], y_train[new Slice(0, 1000)], 
          batch_size: 64, 
          epochs: 10, 
 model.fit(x_train[new Slice(0, 2000)], y_train[new Slice(0, 2000)],
          batch_size: 64,
          epochs: 10,
          validation_split: 0.2f);
 ```
@@ -260,4 +256,4 @@ WeChat Sponsor 微信打赏:
 TensorFlow.NET is a part of [SciSharp STACK](https://scisharp.github.io/SciSharp/)
 <br>
 <a href="http://scisharpstack.org"><img src="https://github.com/SciSharp/SciSharp/blob/master/art/scisharp-stack.png" width="391" height="100" /></a>
 <a href="http://scisharpstack.org"><img src="https://github.com/SciSharp/SciSharp/blob/master/art/scisharp-stack.png" width="391" height="100" /></a>
--- a/src/TensorFlowNET.Core/Operations/array_ops.cs
+++ b/src/TensorFlowNET.Core/Operations/array_ops.cs
@@ -506,6 +506,27 @@ namespace Tensorflow
            }
        }
        public static Tensor where_v2(Tensor condition, object x = null, object y = null, string name = null)
        {
            if (x == null && y == null)
            {
                return tf_with(ops.name_scope(name, "Where", new { condition }), scope =>
                {
                    name = scope;
                    condition = ops.convert_to_tensor(condition, preferred_dtype: dtypes.@bool, name: "condition");
                    return gen_array_ops.where(condition: condition, name: name);
                });
            }
            else if (x != null && y != null)
            {
                return gen_array_ops.select_v2(condition, x, y, name);
            }
            else
            {
                throw new ValueError("x and y must both be non-None or both be None.");
            }
        }
        /// <summary>
        /// Returns the shape of a tensor.
        /// </summary>
--- a/src/TensorFlowNET.Core/Operations/gen_array_ops.cs
+++ b/src/TensorFlowNET.Core/Operations/gen_array_ops.cs
@@ -423,6 +423,21 @@ namespace Tensorflow
            var _op = tf.OpDefLib._apply_op_helper("Select", name, new { condition, t = x, e = y });
            return _op.outputs[0];
        }
        public static Tensor select_v2<Tx, Ty>(Tensor condition, Tx x, Ty y, string name = null)
        {
            if (tf.Context.executing_eagerly())
            {
                var results = tf.Runner.TFE_FastPathExecute(tf.Context, tf.Context.DeviceName,
                    "SelectV2", name,
                    null,
                    condition, x, y);
                return results[0];
            }
            var _op = tf.OpDefLib._apply_op_helper("SelectV2", name, new { condition, t = x, e = y });
            return _op.outputs[0];
        }
        public static Tensor scatter_nd(Tensor indices, Tensor updates, Tensor[] shape, string name = null)
        {
--- a/src/TensorFlowNET.Core/Operations/gen_math_ops.cs
+++ b/src/TensorFlowNET.Core/Operations/gen_math_ops.cs
@@ -714,7 +714,23 @@ namespace Tensorflow
            return _op.outputs[0];
        }
        public static Tensor softplus(Tensor features, string name = null)
        {
            if (tf.Context.executing_eagerly())
            {
                var results = tf.Runner.TFE_FastPathExecute(tf.Context, tf.Context.DeviceName,
                    "Softplus", name,
                    null,
                    features);
                return results[0];
            }
            var _op = tf.OpDefLib._apply_op_helper("Softplus", name, args: new { features });
            return _op.outputs[0];
        }
        public static Tensor cast(Tensor x, TF_DataType DstT, bool Truncate = false, string name = null)
            => tf.Context.RunInAutoMode(()
                => tf.OpDefLib._apply_op_helper("Cast", name, args: new { x, DstT, Truncate }).output, ()
@@ -1068,6 +1084,15 @@ namespace Tensorflow
        public static Tensor _abs(Tensor x, string name = null)
        {
            if (tf.Context.executing_eagerly())
            {
                var results = tf.Runner.TFE_FastPathExecute(tf.Context, tf.Context.DeviceName,
                    "Abs", name,
                     null,
                     x);
                return results[0];
            }
            var _op = tf.OpDefLib._apply_op_helper("Abs", name, args: new { x });
            return _op.output;
@@ -1202,6 +1227,15 @@ namespace Tensorflow
        /// <returns></returns>
        public static Tensor rsqrt(Tensor x, string name = null)
        {
            if (tf.Context.executing_eagerly())
            {
                var results = tf.Runner.TFE_FastPathExecute(tf.Context, tf.Context.DeviceName,
                    "Rsqrt", name,
                    null,
                    x);
                return results[0];
            }
            var _op = tf.OpDefLib._apply_op_helper("Rsqrt", name, new { x });
            return _op.outputs[0];
--- a/src/TensorFlowNET.Core/Operations/nn_impl.py.cs
+++ b/src/TensorFlowNET.Core/Operations/nn_impl.py.cs
@@ -31,7 +31,7 @@ namespace Tensorflow
        /// <returns></returns>
        public static Tensor l2_normalize(Tensor x,
            int axis = 0,
            float epsilon = 1e-12f,
            Tensor epsilon =null,
            string name = null)
        {
            return tf_with(ops.name_scope(name, "l2_normalize", new { x }), scope =>
@@ -39,7 +39,7 @@ namespace Tensorflow
                x = ops.convert_to_tensor(x, name: "x");
                var sq = math_ops.square(x);
                var square_sum = math_ops.reduce_sum(sq, axis, keepdims: true);
                var x_inv_norm = math_ops.rsqrt(math_ops.maximum(square_sum, epsilon));
                var x_inv_norm = math_ops.rsqrt(math_ops.maximum(square_sum, epsilon == null ? tf.Variable(1e-12f) : epsilon));
                return math_ops.multiply(x, x_inv_norm, name: name);
            });
        }
--- a/src/TensorFlowNET.Keras/Losses/CategoricalCrossentropy.cs
+++ b/src/TensorFlowNET.Keras/Losses/CategoricalCrossentropy.cs
@@ -9,18 +9,19 @@ namespace Tensorflow.Keras.Losses
    public class CategoricalCrossentropy : LossFunctionWrapper, ILossFunc
    {
        float label_smoothing;
        public CategoricalCrossentropy(bool from_logits = false,
        public CategoricalCrossentropy(
            bool from_logits = false,
            float label_smoothing = 0,
            string reduction = ReductionV2.AUTO,
            string name = "categorical_crossentropy") :
            base(reduction: reduction, 
                name: name,
                from_logits: from_logits)
            string reduction = null,
            string name = null) :
            base(reduction: reduction,
                 name: name == null ? "categorical_crossentropy" : name, 
                 from_logits: from_logits)
        {
            this.label_smoothing = label_smoothing;
        }
        public override Tensor Apply(Tensor y_true, Tensor y_pred, bool from_logits = false, int axis = -1)
        {
            // Try to adjust the shape so that rank of labels = rank of logits - 1.
--- a/src/TensorFlowNET.Keras/Losses/CosineSimilarity.cs
+++ b/src/TensorFlowNET.Keras/Losses/CosineSimilarity.cs
@@ -0,0 +1,28 @@
 using System;
 using System.Collections.Generic;
 using System.Text;
 using static Tensorflow.Binding;
 using static Tensorflow.KerasApi;
 namespace Tensorflow.Keras.Losses
 {
    public class CosineSimilarity : LossFunctionWrapper, ILossFunc
    {
        protected int axis=-1;
        public CosineSimilarity(
            string reduction = null,
            int axis=-1,
            string name = null) :
            base(reduction: reduction, name: name == null ? "cosine_similarity" : name)
        {
            this.axis = axis;
        }
        public override Tensor Apply(Tensor y_true = null, Tensor y_pred =null, bool from_logits = false, int axis = -1)
        {
            Tensor y_true_normalize = nn_impl.l2_normalize(y_true, axis : this.axis);
            Tensor y_pred_normalize = nn_impl.l2_normalize(y_pred, axis: this.axis);
            return -math_ops.reduce_sum(y_true_normalize * y_pred_normalize, axis : this.axis);
        }
    }
 }
--- a/src/TensorFlowNET.Keras/Losses/Huber.cs
+++ b/src/TensorFlowNET.Keras/Losses/Huber.cs
@@ -0,0 +1,36 @@
 using System;
 using System.Collections.Generic;
 using System.Text;
 using static Tensorflow.Binding;
 using static Tensorflow.KerasApi;
 namespace Tensorflow.Keras.Losses
 {
    public class Huber : LossFunctionWrapper, ILossFunc
    {
        protected Tensor delta = tf.Variable(1.0) ;
        public Huber (
            string reduction = null,
            Tensor delta = null,
            string name = null) :
            base(reduction: reduction, name: name == null ? "huber" : name)
        {
            this.delta = delta==null? this.delta: delta;
        }
        public override Tensor Apply(Tensor y_true = null, Tensor y_pred =null, bool from_logits = false, int axis = -1)
        {
            Tensor y_pred_cast = math_ops.cast(y_pred, dtype: TF_DataType.TF_FLOAT);
            Tensor y_true_cast = math_ops.cast(y_true, dtype: TF_DataType.TF_FLOAT);
            Tensor delta = math_ops.cast(this.delta, dtype: TF_DataType.TF_FLOAT);
            Tensor error = math_ops.subtract(y_pred_cast, y_true_cast);
            Tensor abs_error = math_ops.abs(error);
            Tensor half = ops.convert_to_tensor(0.5, dtype: abs_error.dtype);
            return gen_math_ops.mean(array_ops.where_v2(abs_error <= delta, 
                                                        half * math_ops.pow(error, 2), 
                                                        half * math_ops.pow(delta, 2) + delta * (abs_error - delta)),
                                     axis : -1);
        }
    }
 }
--- a/src/TensorFlowNET.Keras/Losses/ILossFunc.cs
+++ b/src/TensorFlowNET.Keras/Losses/ILossFunc.cs
@@ -2,7 +2,8 @@
 {
    public interface ILossFunc
    {
        string Reduction { get; }
        Tensor Call(Tensor y_true, Tensor y_pred);
        public string Reduction { get; }
        public string Name { get; }
        Tensor Call(Tensor y_true, Tensor y_pred, Tensor sample_weight = null);
    }
 }
--- a/src/TensorFlowNET.Keras/Losses/LogCosh.cs
+++ b/src/TensorFlowNET.Keras/Losses/LogCosh.cs
@@ -0,0 +1,28 @@
 using System;
 using System.Collections.Generic;
 using System.Text;
 using Tensorflow.Operations;
 using static Tensorflow.Binding;
 using static Tensorflow.KerasApi;
 namespace Tensorflow.Keras.Losses
 {
    public class LogCosh : LossFunctionWrapper, ILossFunc
    {
        public LogCosh(
            string reduction = null,
            string name = null) :
            base(reduction: reduction, name: name == null ? "huber" : name){ }
        public override Tensor Apply(Tensor y_true = null, Tensor y_pred =null, bool from_logits = false, int axis = -1)
        {
            Tensor y_pred_dispatch = ops.convert_to_tensor(y_pred);
            Tensor y_true_cast = gen_math_ops.cast(y_true, y_pred_dispatch.dtype);
            Tensor x = y_pred_dispatch - y_true_cast;
            return gen_math_ops.mean(x + gen_math_ops.softplus(-2.0 * x) - math_ops.cast(math_ops.log(tf.Variable(2.0)), x.dtype),axis: -1);
        }
    }
 }
--- a/src/TensorFlowNET.Keras/Losses/Loss.cs
+++ b/src/TensorFlowNET.Keras/Losses/Loss.cs
@@ -15,12 +15,12 @@ namespace Tensorflow.Keras.Losses
        string _name_scope;
        public string Reduction => reduction;
        public string Name => name;
        public Loss(string reduction = ReductionV2.AUTO, 
            string name = null,
            bool from_logits = false)
        {
            this.reduction = reduction;
            this.reduction = reduction == null ? ReductionV2.SUM_OVER_BATCH_SIZE : reduction;
            this.name = name;
            this.from_logits = from_logits;
            _allow_sum_over_batch_size = false;
@@ -31,10 +31,10 @@ namespace Tensorflow.Keras.Losses
            throw new NotImplementedException("");
        }
        public Tensor Call(Tensor y_true, Tensor y_pred)
        public Tensor Call(Tensor y_true, Tensor y_pred, Tensor sample_weight = null)
        {
            var losses = Apply(y_true, y_pred, from_logits: from_logits);
            return losses_utils.compute_weighted_loss(losses, reduction: ReductionV2.SUM_OVER_BATCH_SIZE);
            return losses_utils.compute_weighted_loss(losses, reduction: this.reduction , sample_weight: sample_weight);
        }
        void _set_name_scope()
--- a/src/TensorFlowNET.Keras/Losses/LossesApi.cs
+++ b/src/TensorFlowNET.Keras/Losses/LossesApi.cs
@@ -2,10 +2,31 @@
 {
    public class LossesApi
    {
        public ILossFunc SparseCategoricalCrossentropy(bool from_logits = false)
            => new SparseCategoricalCrossentropy(from_logits: from_logits);
        public ILossFunc SparseCategoricalCrossentropy(string reduction = null, string name = null,bool from_logits = false)
            => new SparseCategoricalCrossentropy(reduction: reduction, name: name,from_logits: from_logits);
        public ILossFunc CategoricalCrossentropy(string reduction = null, string name = null,bool from_logits = false)
            => new CategoricalCrossentropy(reduction: reduction, name: name,from_logits: from_logits);
        public ILossFunc MeanSquaredError(string reduction = null, string name = null)
            => new MeanSquaredError(reduction: reduction, name:name);
        public ILossFunc MeanSquaredLogarithmicError(string reduction = null, string name = null)
           => new MeanSquaredLogarithmicError(reduction: reduction, name: name);
        public ILossFunc MeanAbsolutePercentageError(string reduction = null, string name = null)
           => new MeanAbsolutePercentageError(reduction: reduction, name: name);
        public ILossFunc MeanAbsoluteError(string reduction = null, string name = null)
           => new MeanAbsoluteError(reduction: reduction, name: name);
        public ILossFunc CosineSimilarity(string reduction = null, string name = null,int axis=-1)
            => new CosineSimilarity(reduction: reduction, name: name, axis: axis);
        public ILossFunc Huber(string reduction = null, string name = null, Tensor delta=null)
            => new Huber(reduction: reduction, name: name, delta: delta);
        public ILossFunc LogCosh(string reduction = null, string name = null)
            => new LogCosh(reduction: reduction, name: name);
        public ILossFunc CategoricalCrossentropy(bool from_logits = false)
            => new CategoricalCrossentropy(from_logits: from_logits);
    }
 }
--- a/src/TensorFlowNET.Keras/Losses/MeanAbsoluteError.cs
+++ b/src/TensorFlowNET.Keras/Losses/MeanAbsoluteError.cs
@@ -0,0 +1,23 @@
 using System;
 using System.Collections.Generic;
 using System.Text;
 using static Tensorflow.Binding;
 using static Tensorflow.KerasApi;
 namespace Tensorflow.Keras.Losses
 {
    public class MeanAbsoluteError : LossFunctionWrapper, ILossFunc
    {
        public MeanAbsoluteError(
            string reduction = null,
            string name = null) :
            base(reduction: reduction, name: name == null ? "mean_absolute_error" : name){ }
        public override Tensor Apply(Tensor y_true = null, Tensor y_pred =null, bool from_logits = false, int axis = -1)
        {
            Tensor y_pred_dispatch = ops.convert_to_tensor(y_pred);
            Tensor y_true_cast = gen_math_ops.cast(y_true, y_pred_dispatch.dtype);
            return  gen_math_ops.mean(math_ops.abs(y_pred_dispatch - y_true_cast), axis: -1);
        }
    }
 }
--- a/src/TensorFlowNET.Keras/Losses/MeanAbsolutePercentageError.cs
+++ b/src/TensorFlowNET.Keras/Losses/MeanAbsolutePercentageError.cs
@@ -0,0 +1,24 @@
 using System;
 using System.Collections.Generic;
 using System.Text;
 using static Tensorflow.Binding;
 using static Tensorflow.KerasApi;
 namespace Tensorflow.Keras.Losses
 {
    public class MeanAbsolutePercentageError : LossFunctionWrapper, ILossFunc
    {
        public MeanAbsolutePercentageError(
            string reduction = null,
            string name = null) :
            base(reduction: reduction, name: name == null ? "mean_absolute_percentage_error" : name){ }
        public override Tensor Apply(Tensor y_true = null, Tensor y_pred =null, bool from_logits = false, int axis = -1)
        {
            Tensor y_pred_dispatch = ops.convert_to_tensor(y_pred);
            Tensor y_true_cast = gen_math_ops.cast(y_true, y_pred_dispatch.dtype);
            Tensor diff = math_ops.abs(y_true_cast - y_pred_dispatch) / gen_math_ops.maximum(math_ops.abs(y_true_cast), gen_math_ops.cast(tf.constant(1e-7), y_pred_dispatch.dtype));
            return gen_math_ops.cast(tf.constant(100), y_pred_dispatch.dtype) *gen_math_ops.mean(diff, axis: -1);
        }
    }
 }
--- a/src/TensorFlowNET.Keras/Losses/MeanSquaredError.cs
+++ b/src/TensorFlowNET.Keras/Losses/MeanSquaredError.cs
@@ -0,0 +1,23 @@
 using System;
 using System.Collections.Generic;
 using System.Text;
 using static Tensorflow.Binding;
 using static Tensorflow.KerasApi;
 namespace Tensorflow.Keras.Losses
 {
    public class MeanSquaredError : LossFunctionWrapper, ILossFunc
    {
        public MeanSquaredError(
            string reduction = null,
            string name = null) :
            base(reduction: reduction, name: name==null? "mean_squared_error" : name){ }
        public override Tensor Apply(Tensor y_true = null, Tensor y_pred =null, bool from_logits = false, int axis = -1)
        {
            Tensor y_pred_dispatch = ops.convert_to_tensor(y_pred);
            Tensor y_true_cast = gen_math_ops.cast(y_true, y_pred_dispatch.dtype);
            return  gen_math_ops.mean(gen_math_ops.squared_difference(y_pred_dispatch, y_true_cast), axis: -1);
        }
    }
 }
--- a/src/TensorFlowNET.Keras/Losses/MeanSquaredLogarithmicError.cs
+++ b/src/TensorFlowNET.Keras/Losses/MeanSquaredLogarithmicError.cs
@@ -0,0 +1,33 @@
 using System;
 using System.Collections.Generic;
 using System.Text;
 using static Tensorflow.Binding;
 using static Tensorflow.KerasApi;
 namespace Tensorflow.Keras.Losses
 {
    public class MeanSquaredLogarithmicError : LossFunctionWrapper, ILossFunc
    {
        public MeanSquaredLogarithmicError(
            string reduction = null,
            string name = null) :
            base(reduction: reduction, name: name == null ? "mean_squared_logarithmic_error" : name){ }
        public override Tensor Apply(Tensor y_true = null, Tensor y_pred =null, bool from_logits = false, int axis = -1)
        {
            Tensor y_pred_dispatch = ops.convert_to_tensor(y_pred);
            Tensor y_true_cast = gen_math_ops.cast(y_true, y_pred_dispatch.dtype);
            Tensor first_log=null, second_log=null;
            if (y_pred_dispatch.dtype == TF_DataType.TF_DOUBLE) {
                first_log = math_ops.log(gen_math_ops.maximum(y_pred_dispatch, 1e-7) + 1.0);
                second_log = math_ops.log(gen_math_ops.maximum(y_true_cast, 1e-7) + 1.0);
            }
            else {
                first_log = math_ops.log(gen_math_ops.maximum(y_pred_dispatch, 1e-7f) + 1.0f);
                second_log = math_ops.log(gen_math_ops.maximum(y_true_cast, 1e-7f) + 1.0f);
            }
            return gen_math_ops.mean(gen_math_ops.squared_difference(first_log, second_log), axis: -1);
        }
    }
 }
--- a/src/TensorFlowNET.Keras/Losses/ReductionV2.cs
+++ b/src/TensorFlowNET.Keras/Losses/ReductionV2.cs
@@ -4,6 +4,7 @@
    {
        public const string NONE = "none";
        public const string AUTO = "auto";
        public const string SUM = "sum";
        public const string SUM_OVER_BATCH_SIZE = "sum_over_batch_size";
        public const string WEIGHTED_MEAN = "weighted_mean";
    }
--- a/src/TensorFlowNET.Keras/Losses/SparseCategoricalCrossentropy.cs
+++ b/src/TensorFlowNET.Keras/Losses/SparseCategoricalCrossentropy.cs
@@ -4,14 +4,11 @@ namespace Tensorflow.Keras.Losses
 {
    public class SparseCategoricalCrossentropy : LossFunctionWrapper, ILossFunc
    {
        public SparseCategoricalCrossentropy(bool from_logits = false,
            string reduction = ReductionV2.AUTO,
            string name = "sparse_categorical_crossentropy") :
            base(reduction: reduction,
                name: name)
        {
        }
        public SparseCategoricalCrossentropy(
            bool from_logits = false,
            string reduction = null,
            string name = null) :
            base(reduction: reduction, name: name == null ? "sparse_categorical_crossentropy" : name){ }
        public override Tensor Apply(Tensor target, Tensor output, bool from_logits = false, int axis = -1)
        {
--- a/test/TensorFlowNET.UnitTest/Keras/CosineSimilarity.Test.cs
+++ b/test/TensorFlowNET.UnitTest/Keras/CosineSimilarity.Test.cs
@@ -0,0 +1,76 @@
 using Microsoft.VisualStudio.TestTools.UnitTesting;
 using NumSharp;
 using Tensorflow;
 using Tensorflow.Keras.Losses;
 using static Tensorflow.Binding;
 using static Tensorflow.KerasApi;
 namespace TensorFlowNET.UnitTest.Keras
 {
    [TestClass]
    public class CosineSimilarity
    {
        //https://keras.io/api/losses/regression_losses/
        NDArray y_true_float = new float[,] { { 0.0f, 1.0f }, { 1.0f, 1.0f } };
        NDArray y_pred_float = new float[,] { { 1.0f, 0.0f }, { 1.0f, 1.0f } };
        [TestMethod]
        public void _Default()
        {
            //>>> # Using 'auto'/'sum_over_batch_size' reduction type.  
            //>>> cosine_loss = tf.keras.losses.CosineSimilarity(axis = 1)
            //>>> # l2_norm(y_true) = [[0., 1.], [1./1.414], 1./1.414]]]  
            //>>> # l2_norm(y_pred) = [[1., 0.], [1./1.414], 1./1.414]]]  
            //>>> # l2_norm(y_true) . l2_norm(y_pred) = [[0., 0.], [0.5, 0.5]]  
            //>>> # loss = mean(sum(l2_norm(y_true) . l2_norm(y_pred), axis=1))  
            //>>> #       = -((0. + 0.) +  (0.5 + 0.5)) / 2  
            //-0.5
            var loss = keras.losses.CosineSimilarity(axis : 1);
            var call = loss.Call(y_true_float, y_pred_float);
            Assert.AreEqual((NDArray)(-0.49999997f), call.numpy());
        }
        [TestMethod]
        public void _Sample_Weight()
        {
            //>>> # Calling with 'sample_weight'.  
            //>>> cosine_loss(y_true, y_pred, sample_weight =[0.8, 0.2]).numpy()
            //- 0.0999
            var loss = keras.losses.CosineSimilarity();
            var call = loss.Call(y_true_float, y_pred_float, sample_weight: (NDArray)new float[] { 0.8f, 0.2f });
            Assert.AreEqual((NDArray) (- 0.099999994f), call.numpy());
        }
        [TestMethod]
        public void _SUM()
        {
            //>>> # Using 'sum' reduction type.  
            //>>> cosine_loss = tf.keras.losses.CosineSimilarity(axis = 1,
            //...     reduction = tf.keras.losses.Reduction.SUM)
            //>>> cosine_loss(y_true, y_pred).numpy()
            //- 0.999
            var loss = keras.losses.CosineSimilarity(axis: 1,reduction : ReductionV2.SUM);
            var call = loss.Call(y_true_float, y_pred_float);
            Assert.AreEqual((NDArray)(-0.99999994f), call.numpy());
        }
        [TestMethod]
        public void _None()
        {
            //>>> # Using 'none' reduction type.  
            //>>> cosine_loss = tf.keras.losses.CosineSimilarity(axis = 1,
            //...     reduction = tf.keras.losses.Reduction.NONE)
            //>>> cosine_loss(y_true, y_pred).numpy()
            //array([-0., -0.999], dtype = float32)
            var loss = keras.losses.CosineSimilarity(axis :1, reduction: ReductionV2.NONE);
            var call = loss.Call(y_true_float, y_pred_float);
            Assert.AreEqual((NDArray)new float[] { -0f, -0.99999994f }, call.numpy());
        }
    }
 }
--- a/test/TensorFlowNET.UnitTest/Keras/Huber.Test.cs
+++ b/test/TensorFlowNET.UnitTest/Keras/Huber.Test.cs
@@ -0,0 +1,72 @@
 using Microsoft.VisualStudio.TestTools.UnitTesting;
 using NumSharp;
 using Tensorflow;
 using Tensorflow.Keras.Losses;
 using static Tensorflow.Binding;
 using static Tensorflow.KerasApi;
 namespace TensorFlowNET.UnitTest.Keras
 {
    [TestClass]
    public class Huber
    {
        //https://keras.io/api/losses/regression_losses/#meansquarederror-class
        NDArray y_true_float = new float[,] { { 0.0f, 1.0f }, { 0.0f, 0.0f } };
        NDArray y_pred_float = new float[,] { { 0.6f, 0.4f }, { 0.4f, 0.6f } };
        [TestMethod]
        public void _Default()
        {
            //>>> # Using 'auto'/'sum_over_batch_size' reduction type.  
            //>>> h = tf.keras.losses.Huber()
            //>>> h(y_true, y_pred).numpy()
            //0.155
            var loss = keras.losses.Huber();
            var call = loss.Call(y_true_float, y_pred_float);
            Assert.AreEqual((NDArray)0.155f, call.numpy());
        }
        [TestMethod]
        public void _Sample_Weight()
        {
            //>>> # Calling with 'sample_weight'.  
            //>>> h(y_true, y_pred, sample_weight =[1, 0]).numpy()
            //0.09
            var loss = keras.losses.Huber();
            var call = loss.Call(y_true_float, y_pred_float, sample_weight: (NDArray)new float[] { 0.1f, 0.0f });
            Assert.AreEqual((NDArray)0.009000001f, call.numpy());
        }
        [TestMethod]
        public void _SUM()
        {
            //>>> # Using 'sum' reduction type.  
            //>>> h = tf.keras.losses.Huber(
            //...     reduction = tf.keras.losses.Reduction.SUM)
            //>>> h(y_true, y_pred).numpy()
            //0.31
            var loss = keras.losses.Huber(reduction : ReductionV2.SUM);
            var call = loss.Call(y_true_float, y_pred_float);
            Assert.AreEqual((NDArray)0.31f, call.numpy());
        }
        [TestMethod]
        public void _None()
        {
            //>>> # Using 'none' reduction type.  
            //>>> h = tf.keras.losses.Huber(
            //...     reduction = tf.keras.losses.Reduction.NONE)
            //>>> h(y_true, y_pred).numpy()
            //array([0.18, 0.13], dtype = float32)
            var loss = keras.losses.Huber(reduction: ReductionV2.NONE);
            var call = loss.Call(y_true_float, y_pred_float);
            Assert.AreEqual((NDArray)new float[] { 0.18f, 0.13000001f }, call.numpy());
        }
    }
 }
--- a/test/TensorFlowNET.UnitTest/Keras/LogCosh.Test.cs
+++ b/test/TensorFlowNET.UnitTest/Keras/LogCosh.Test.cs
@@ -0,0 +1,72 @@
 using Microsoft.VisualStudio.TestTools.UnitTesting;
 using NumSharp;
 using Tensorflow;
 using Tensorflow.Keras.Losses;
 using static Tensorflow.Binding;
 using static Tensorflow.KerasApi;
 namespace TensorFlowNET.UnitTest.Keras
 {
    [TestClass]
    public class LogCosh
    {
        //https://keras.io/api/losses/regression_losses/#meansquarederror-class
        NDArray y_true_float = new float[,] { { 0.0f, 1.0f }, { 0.0f, 0.0f } };
        NDArray y_pred_float = new float[,] { { 1.0f, 1.0f }, { 0.0f, 0.0f } };
        [TestMethod]
        public void _Default()
        {
            //>>> # Using 'auto'/'sum_over_batch_size' reduction type.  
            //>>> l = tf.keras.losses.LogCosh()
            //>>> l(y_true, y_pred).numpy()
            //0.108
            var loss = keras.losses.LogCosh();
            var call = loss.Call(y_true_float, y_pred_float);
            Assert.AreEqual((NDArray)0.1084452f, call.numpy());
        }
        [TestMethod]
        public void _Sample_Weight()
        {
        //>>> # Calling with 'sample_weight'.  
        //>>> l(y_true, y_pred, sample_weight =[0.8, 0.2]).numpy()
        //0.087
            var loss = keras.losses.LogCosh();
            var call = loss.Call(y_true_float, y_pred_float, sample_weight: (NDArray)new float[] { 0.8f, 0.2f });
            Assert.AreEqual((NDArray)0.08675616f, call.numpy());
        }
        [TestMethod]
        public void _SUM()
        {
            //>>> # Using 'sum' reduction type.  
            //>>> l = tf.keras.losses.LogCosh(
            //...     reduction = tf.keras.losses.Reduction.SUM)
            //>>> l(y_true, y_pred).numpy()
            //0.217
            var loss = keras.losses.LogCosh(reduction : ReductionV2.SUM);
            var call = loss.Call(y_true_float, y_pred_float);
            Assert.AreEqual((NDArray)0.2168904f, call.numpy());
        }
        [TestMethod]
        public void _None()
        {
            //>>> # Using 'none' reduction type.  
            //>>> l = tf.keras.losses.LogCosh(
            //...     reduction = tf.keras.losses.Reduction.NONE)
            //>>> l(y_true, y_pred).numpy()
            //array([0.217, 0.], dtype = float32)
            var loss = keras.losses.LogCosh(reduction: ReductionV2.NONE);
            var call = loss.Call(y_true_float, y_pred_float);
            Assert.AreEqual((NDArray)new float[] { 0.2168904f, 0.0f }, call.numpy());
        }
    }
 }
--- a/test/TensorFlowNET.UnitTest/Keras/MeanAbsoluteError.Test.cs
+++ b/test/TensorFlowNET.UnitTest/Keras/MeanAbsoluteError.Test.cs
@@ -0,0 +1,73 @@
 using Microsoft.VisualStudio.TestTools.UnitTesting;
 using NumSharp;
 using Tensorflow;
 using Tensorflow.Keras.Losses;
 using static Tensorflow.Binding;
 using static Tensorflow.KerasApi;
 namespace TensorFlowNET.UnitTest.Keras
 {
    [TestClass]
    public class MeanAbsoluteError
    {
        //https://keras.io/api/losses/regression_losses/
        NDArray y_true_float = new float[,] { { 0.0f, 1.0f }, { 0.0f, 0.0f } };
        NDArray y_pred_float = new float[,] { { 1.0f, 1.0f }, { 1.0f, 0.0f } };
        [TestMethod]
        public void _Default()
        {
            //>>> # Using 'auto'/'sum_over_batch_size' reduction type.  
            //>>> mae = tf.keras.losses.MeanAbsoluteError()
            //>>> mae(y_true, y_pred).numpy()
            //0.5
            var loss = keras.losses.MeanAbsoluteError();
            var call = loss.Call(y_true_float, y_pred_float);
            Assert.AreEqual((NDArray)(0.5f), call.numpy());
        }
        [TestMethod]
        public void _Sample_Weight()
        {
            //>>> # Calling with 'sample_weight'.  
            //>>> mae(y_true, y_pred, sample_weight =[0.7, 0.3]).numpy()
            //0.25
            var loss = keras.losses.MeanAbsoluteError();
            var call = loss.Call(y_true_float, y_pred_float, sample_weight: (NDArray)new float[] { 0.7f, 0.3f });
            Assert.AreEqual((NDArray)(0.25f), call.numpy());
        }
        [TestMethod]
        public void _SUM()
        {
            //>>> # Using 'sum' reduction type.  
            //>>> mae = tf.keras.losses.MeanAbsoluteError(
            //...     reduction = tf.keras.losses.Reduction.SUM)
            //>>> mae(y_true, y_pred).numpy()
            //1.0
            var loss = keras.losses.MeanAbsoluteError( reduction: ReductionV2.SUM);
            var call = loss.Call(y_true_float, y_pred_float);
            Assert.AreEqual((NDArray)(1.0f), call.numpy());
        }
        [TestMethod]
        public void _None()
        {
            //>>> # Using 'none' reduction type.  
            //>>> mae = tf.keras.losses.MeanAbsoluteError(
            //...     reduction = tf.keras.losses.Reduction.NONE)
            //>>> mae(y_true, y_pred).numpy()
            //array([0.5, 0.5], dtype = float32)
            var loss = keras.losses.MeanAbsoluteError(reduction: ReductionV2.NONE);
            var call = loss.Call(y_true_float, y_pred_float);
            Assert.AreEqual((NDArray)new float[] { 0.5f, 0.5f }, call.numpy());
        }
    }
 }
--- a/test/TensorFlowNET.UnitTest/Keras/MeanAbsolutePercentageError.Test.cs
+++ b/test/TensorFlowNET.UnitTest/Keras/MeanAbsolutePercentageError.Test.cs
@@ -0,0 +1,72 @@
 using Microsoft.VisualStudio.TestTools.UnitTesting;
 using NumSharp;
 using Tensorflow;
 using Tensorflow.Keras.Losses;
 using static Tensorflow.Binding;
 using static Tensorflow.KerasApi;
 namespace TensorFlowNET.UnitTest.Keras
 {
    [TestClass]
    public class MeanAbsolutePercentageError
    {
        //https://keras.io/api/losses/regression_losses/
        NDArray y_true_float = new float[,] { { 2.0f, 1.0f }, { 2.0f, 3.0f } };
        NDArray y_pred_float = new float[,] { { 1.0f, 1.0f }, { 1.0f, 0.0f } };
        [TestMethod]
        public void _Default()
        {
            //>>> # Using 'auto'/'sum_over_batch_size' reduction type.  
            //>>> mape = tf.keras.losses.MeanAbsolutePercentageError()
            //>>> mape(y_true, y_pred).numpy()
            //50.
            var loss = keras.losses.MeanAbsolutePercentageError();
            var call = loss.Call(y_true_float, y_pred_float);
            Assert.AreEqual((NDArray)(50f), call.numpy());
        }
        [TestMethod]
        public void _Sample_Weight()
        {
            //>>> # Calling with 'sample_weight'.  
            //>>> mape(y_true, y_pred, sample_weight =[0.7, 0.3]).numpy()
            //20.
            var loss = keras.losses.MeanAbsolutePercentageError();
            var call = loss.Call(y_true_float, y_pred_float, sample_weight: (NDArray)new float[] { 0.7f, 0.3f });
            Assert.AreEqual((NDArray)(20f), call.numpy());
        }
        [TestMethod]
        public void _SUM()
        {
            //>>> # Using 'sum' reduction type.  
            //>>> mape = tf.keras.losses.MeanAbsolutePercentageError(
            //...     reduction = tf.keras.losses.Reduction.SUM)
            //>>> mape(y_true, y_pred).numpy()
            //100.
            var loss = keras.losses.MeanAbsolutePercentageError( reduction: ReductionV2.SUM);
            var call = loss.Call(y_true_float, y_pred_float);
            Assert.AreEqual((NDArray)(100f), call.numpy());
        }
        [TestMethod]
        public void _None()
        {
            //>>> # Using 'none' reduction type.  
            //>>> mape = tf.keras.losses.MeanAbsolutePercentageError(
            //...     reduction = tf.keras.losses.Reduction.NONE)
            //>>> mape(y_true, y_pred).numpy()
            //array([25., 75.], dtype = float32)
            var loss = keras.losses.MeanAbsolutePercentageError(reduction: ReductionV2.NONE);
            var call = loss.Call(y_true_float, y_pred_float);
            Assert.AreEqual((NDArray)new float[] { 25f, 75f }, call.numpy());
        }
    }
 }
--- a/test/TensorFlowNET.UnitTest/Keras/MeanSquaredError.Test.cs
+++ b/test/TensorFlowNET.UnitTest/Keras/MeanSquaredError.Test.cs
@@ -0,0 +1,65 @@
 using Microsoft.VisualStudio.TestTools.UnitTesting;
 using NumSharp;
 using Tensorflow;
 using Tensorflow.Keras.Losses;
 using static Tensorflow.Binding;
 using static Tensorflow.KerasApi;
 namespace TensorFlowNET.UnitTest.Keras
 {
    [TestClass]
    public class MeanSquaredErrorTest 
    {
        //https://keras.io/api/losses/regression_losses/#meansquarederror-class
        private NDArray y_true = new double[,] { { 0.0, 1.0 }, { 0.0, 0.0 } };
        private NDArray y_pred = new double[,] { { 1.0, 1.0 }, { 1.0, 0.0 } };
        [TestMethod]
        public void Mse_Double()
        {
            var mse = keras.losses.MeanSquaredError();
            var call = mse.Call(y_true, y_pred);
            Assert.AreEqual((NDArray)0.5, call.numpy()) ;
        }
        [TestMethod]
        public void Mse_Float()
        {
            NDArray y_true_float = new float[,] { { 0.0f, 1.0f }, { 0.0f, 0.0f } };
            NDArray y_pred_float = new float[,] { { 1.0f, 1.0f }, { 1.0f, 0.0f } };
            var mse = keras.losses.MeanSquaredError();
            var call = mse.Call(y_true_float, y_pred_float);
            Assert.AreEqual((NDArray)0.5, call.numpy());
        }
        [TestMethod]
        public void Mse_Sample_Weight()
        {
            var mse = keras.losses.MeanSquaredError();
            var call = mse.Call(y_true, y_pred, sample_weight: (NDArray)new double[] { 0.7, 0.3 });
            Assert.AreEqual((NDArray)0.25, call.numpy());
        }
        [TestMethod]
        public void Mse_Reduction_SUM()
        {
            var mse = keras.losses.MeanSquaredError(reduction: Reduction.SUM);
            var call = mse.Call(y_true, y_pred);
            Assert.AreEqual((NDArray)1.0, call.numpy());
        }
        [TestMethod]
        public void Mse_Reduction_NONE()
        {
            var mse = keras.losses.MeanSquaredError(reduction: Reduction.NONE);
            var call = mse.Call(y_true, y_pred);
            Assert.AreEqual((NDArray)new double[] { 0.5, 0.5 }, call.numpy());
        }
    }
 }
--- a/test/TensorFlowNET.UnitTest/Keras/MeanSquaredLogarithmicError.Test.cs
+++ b/test/TensorFlowNET.UnitTest/Keras/MeanSquaredLogarithmicError.Test.cs
@@ -0,0 +1,72 @@
 using Microsoft.VisualStudio.TestTools.UnitTesting;
 using NumSharp;
 using Tensorflow;
 using Tensorflow.Keras.Losses;
 using static Tensorflow.Binding;
 using static Tensorflow.KerasApi;
 namespace TensorFlowNET.UnitTest.Keras
 {
    [TestClass]
    public class MeanSquaredLogarithmicError
    {
        //https://keras.io/api/losses/regression_losses/
        NDArray y_true_float = new float[,] { { 0.0f, 1.0f }, { 0.0f, 0.0f } };
        NDArray y_pred_float = new float[,] { { 1.0f, 1.0f }, { 1.0f, 0.0f } };
        [TestMethod]
        public void _Default()
        {
            //>>> # Using 'auto'/'sum_over_batch_size' reduction type.  
            //>>> msle = tf.keras.losses.MeanSquaredLogarithmicError()
            //>>> msle(y_true, y_pred).numpy()
            //0.240
            var loss = keras.losses.MeanSquaredLogarithmicError();
            var call = loss.Call(y_true_float, y_pred_float);
            Assert.AreEqual((NDArray)(0.24022643f), call.numpy());
        }
        [TestMethod]
        public void _Sample_Weight()
        {
            //>>> # Calling with 'sample_weight'.  
            //>>> msle(y_true, y_pred, sample_weight =[0.7, 0.3]).numpy()
            //0.120
            var loss = keras.losses.MeanSquaredLogarithmicError();
            var call = loss.Call(y_true_float, y_pred_float, sample_weight: (NDArray)new float[] { 0.7f, 0.3f });
            Assert.AreEqual((NDArray)(0.12011322f), call.numpy());
        }
        [TestMethod]
        public void _SUM()
        {
            //>>> # Using 'sum' reduction type.  
            //>>> msle = tf.keras.losses.MeanSquaredLogarithmicError(
            //...     reduction = tf.keras.losses.Reduction.SUM)
            //>>> msle(y_true, y_pred).numpy()
            //0.480
            var loss = keras.losses.MeanSquaredLogarithmicError( reduction: ReductionV2.SUM);
            var call = loss.Call(y_true_float, y_pred_float);
            Assert.AreEqual((NDArray)(0.48045287f), call.numpy());
        }
        [TestMethod]
        public void _None()
        {
            //>>> # Using 'none' reduction type.  
            //>>> msle = tf.keras.losses.MeanSquaredLogarithmicError(
            //...     reduction = tf.keras.losses.Reduction.NONE)
            //>>> msle(y_true, y_pred).numpy()
            //array([0.240, 0.240], dtype = float32)
            var loss = keras.losses.MeanSquaredLogarithmicError(reduction: ReductionV2.NONE);
            var call = loss.Call(y_true_float, y_pred_float);
            Assert.AreEqual((NDArray)new float[] { 0.24022643f, 0.24022643f }, call.numpy());
        }
    }
 }