add reconstruction and setstate of NDArray for loading pickled npy file.

2 years ago · 9d10daf30f
--- a/src/TensorFlowNET.Core/NumPy/DtypeConstructor.cs
+++ b/src/TensorFlowNET.Core/NumPy/DtypeConstructor.cs
@@ -16,25 +16,50 @@ namespace Tensorflow.NumPy
    {
        public object construct(object[] args)
        {
            Console.WriteLine("DtypeConstructor");
            Console.WriteLine(args.Length);
            for (int i = 0; i < args.Length; i++)
            {
                Console.WriteLine(args[i]);
            }
            return new demo();
            var typeCode = (string)args[0];
            TF_DataType dtype;
            if (typeCode == "b1")
                dtype = np.@bool;
            else if (typeCode == "i1")
                dtype = np.@byte;
            else if (typeCode == "i2")
                dtype = np.int16;
            else if (typeCode == "i4")
                dtype = np.int32;
            else if (typeCode == "i8")
                dtype = np.int64;
            else if (typeCode == "u1")
                dtype = np.ubyte;
            else if (typeCode == "u2")
                dtype = np.uint16;
            else if (typeCode == "u4")
                dtype = np.uint32;
            else if (typeCode == "u8")
                dtype = np.uint64;
            else if (typeCode == "f4")
                dtype = np.float32;
            else if (typeCode == "f8")
                dtype = np.float64;
            else if (typeCode.StartsWith("S"))
                dtype = np.@string;
            else if (typeCode.StartsWith("O"))
                dtype = np.@object;
            else
                throw new NotSupportedException();
            return new TF_DataType_Warpper(dtype);
        }
    }
    class demo
    public class TF_DataType_Warpper
    {
        public void __setstate__(object[] args)
        TF_DataType dtype { get; set; }
        public TF_DataType_Warpper(TF_DataType dtype)
        {
            Console.WriteLine("demo __setstate__");
            Console.WriteLine(args.Length);
            for (int i = 0; i < args.Length; i++)
            {
                Console.WriteLine(args[i]);
            }
            this.dtype = dtype;
        }
        public void __setstate__(object[] args) { }
        public static implicit operator TF_DataType(TF_DataType_Warpper dtypeWarpper)
        {
            return dtypeWarpper.dtype;
        }
    }
 }
--- a/src/TensorFlowNET.Core/NumPy/Implementation/NumPyImpl.Creation.cs
+++ b/src/TensorFlowNET.Core/NumPy/Implementation/NumPyImpl.Creation.cs
@@ -99,9 +99,6 @@ namespace Tensorflow.NumPy
        NDArray ReadObjectMatrix(BinaryReader reader, Array matrix, int[] shape)
        {
            //int data = reader.ReadByte();
            //Console.WriteLine(data);
            //Console.WriteLine(reader.ReadByte());
            Stream stream = reader.BaseStream;
            Unpickler.registerConstructor("numpy.core.multiarray", "_reconstruct", new MultiArrayConstructor());
            Unpickler.registerConstructor("numpy", "dtype", new DtypeConstructor());
--- a/src/TensorFlowNET.Core/NumPy/Implementation/NumPyImpl.load.cs
+++ b/src/TensorFlowNET.Core/NumPy/Implementation/NumPyImpl.load.cs
@@ -28,17 +28,17 @@ namespace Tensorflow.NumPy
                //if (type == typeof(String))
                //return ReadStringMatrix(reader, matrix, bytes, type, shape);
                NDArray res = ReadObjectMatrix(reader, matrix, shape);
                Console.WriteLine("LoadMatrix");
                Console.WriteLine(res.dims[0]);
                Console.WriteLine((int)res[0][0]);
                Console.WriteLine(res.dims[1]);
                //if (type == typeof(Object))
                //{
                //}
                //else 
                return ReadValueMatrix(reader, matrix, bytes, type, shape);
                if (type == typeof(Object))
                {
                    NDArray res = ReadObjectMatrix(reader, matrix, shape);
                    // res = res.reconstructedNDArray;
                    return res.reconstructedArray;
                }
                else
                {
                    return ReadValueMatrix(reader, matrix, bytes, type, shape);
                }
            }
        }
@@ -133,7 +133,7 @@ namespace Tensorflow.NumPy
                return typeof(Double);
            if (typeCode.StartsWith("S"))
                return typeof(String);
            if (typeCode == "O")
            if (typeCode.StartsWith("O"))
                return typeof(Object);
            throw new NotSupportedException();
--- a/src/TensorFlowNET.Core/NumPy/MultiArrayConstructor.cs
+++ b/src/TensorFlowNET.Core/NumPy/MultiArrayConstructor.cs
@@ -3,6 +3,7 @@ using System.Collections.Generic;
 using System.Diagnostics.CodeAnalysis;
 using System.Text;
 using Razorvine.Pickle;
 using Razorvine.Pickle.Objects;
 namespace Tensorflow.NumPy
 {
@@ -17,28 +18,36 @@ namespace Tensorflow.NumPy
    {
        public object construct(object[] args)
        {
            //Console.WriteLine(args.Length);
            //for (int i = 0; i < args.Length; i++)
            //{
            //    Console.WriteLine(args[i]);
            //}
            Console.WriteLine("MultiArrayConstructor");
            if (args.Length != 3) 
                throw new InvalidArgumentError($"Invalid number of arguments in MultiArrayConstructor._reconstruct. Expected three arguments. Given {args.Length} arguments.");
            var types = (ClassDictConstructor)args[0];
            if (types.module != "numpy" || types.name != "ndarray") 
                throw new RuntimeError("_reconstruct: First argument must be a sub-type of ndarray");
            var arg1 = (Object[])args[1];
            var dims = new int[arg1.Length];
            for (var i = 0; i < arg1.Length; i++)
            {
                dims[i] = (int)arg1[i];
            }
            var shape = new Shape(dims);
            var dtype = TF_DataType.DtInvalid;
            switch (args[2])
            TF_DataType dtype;
            string identifier;
            if (args[2].GetType() == typeof(string))
                identifier = (string)args[2];
            else
                identifier = Encoding.UTF8.GetString((byte[])args[2]);
            switch (identifier)
            {
                case "b": dtype = TF_DataType.DtUint8Ref; break;
                default: throw new NotImplementedException("cannot parse" + args[2]);
                case "u": dtype = np.uint32; break;
                case "c": dtype = np.complex_; break;
                case "f": dtype = np.float32; break;
                case "b": dtype = np.@bool; break;
                default: throw new NotImplementedException($"Unsupported data type: {args[2]}");
            }
            return new NDArray(new Shape(dims), dtype);
            return new NDArray(shape, dtype);
        }
    }
 }
--- a/src/TensorFlowNET.Core/NumPy/NDArray.Pickle.cs
+++ b/src/TensorFlowNET.Core/NumPy/NDArray.Pickle.cs
@@ -1,4 +1,7 @@
 using System;
 using Newtonsoft.Json.Linq;
 using Serilog.Debugging;
 using System;
 using System.Collections;
 using System.Collections.Generic;
 using System.Text;
@@ -6,14 +9,100 @@ namespace Tensorflow.NumPy
 {
    public partial class NDArray
    {
        public NDArray reconstructedNDArray { get; set; }
        public Array reconstructedArray { get; set; }
        public void __setstate__(object[] args)
        {
            Console.WriteLine("NDArray __setstate__");
            Console.WriteLine(args.Length);
            for (int i = 0; i < args.Length; i++)
            if (args.Length != 5)
                throw new InvalidArgumentError($"Invalid number of arguments in NDArray.__setstate__. Expected five arguments. Given {args.Length} arguments.");
            var version = (int)args[0]; // version
            var arg1 = (Object[])args[1];
            var dims = new int[arg1.Length];
            for (var i = 0; i < arg1.Length; i++)
            {
                dims[i] = (int)arg1[i];
            }
            var _ShapeLike = new Shape(dims); // shape
            TF_DataType _DType_co = (TF_DataType_Warpper)args[2]; // DType
            var F_continuous = (bool)args[3]; // F-continuous
            if (F_continuous)
                throw new InvalidArgumentError("Fortran Continuous memory layout is not supported. Please use C-continuous layout or check the data format.");
            var data = args[4]; // Data
            /*
             * If we ever need another pickle format, increment the version
             * number. But we should still be able to handle the old versions.
             */
            if (version < 0 || version > 4)
                throw new ValueError($"can't handle version {version} of numpy.dtype pickle");
            // TODO: Implement the missing details and checks from the official Numpy C code here.
            // https://github.com/numpy/numpy/blob/2f0bd6e86a77e4401d0384d9a75edf9470c5deb6/numpy/core/src/multiarray/descriptor.c#L2761
            if (data.GetType() == typeof(ArrayList))
            {
                SetState((ArrayList)data);
            }
            else
                throw new NotImplementedException("");
        }
        private void SetState(ArrayList arrayList)
        {
            int ndim = 1;
            var subArrayList = arrayList;
            while (subArrayList.Count > 0 && subArrayList[0] != null && subArrayList[0].GetType() == typeof(ArrayList))
            {
                subArrayList = (ArrayList)subArrayList[0];
                ndim += 1;
            }
            var type = subArrayList[0].GetType();
            if (type == typeof(int))
            {
                Console.WriteLine(args[i]);
                if (ndim == 1)
                {
                    int[] list = (int[])arrayList.ToArray(typeof(int));
                    Shape shape = new Shape(new int[] { arrayList.Count });
                    reconstructedArray = list;
                    reconstructedNDArray = new NDArray(list, shape);
                    //SetData(new[] { new Slice() }, new NDArray(list, shape));
                    //set_shape(shape);
                }
                if (ndim == 2)
                {
                    int secondDim = 0;
                    foreach (ArrayList subArray in arrayList)
                    {
                        secondDim = subArray.Count > secondDim ? subArray.Count : secondDim;
                    }
                    int[,] list = new int[arrayList.Count, secondDim];
                    for (int i = 0; i < arrayList.Count; i++)
                    {
                        var subArray = (ArrayList?)arrayList[i];
                        if (subArray == null)
                            throw new NullReferenceException("");
                        for (int j = 0; j < subArray.Count; j++)
                        {
                            var element = subArray[j];
                            if (element == null)
                                throw new NoNullAllowedException("the element of ArrayList cannot be null.");
                            list[i,j] = (int) element;
                        }
                    }
                    Shape shape = new Shape(new int[] { arrayList.Count, secondDim });
                    reconstructedArray = list;
                    reconstructedNDArray = new NDArray(list, shape);
                    //SetData(new[] { new Slice() }, new NDArray(list, shape));
                    //set_shape(shape);
                }
                if (ndim > 2)
                    throw new NotImplementedException("can't handle ArrayList with more than two dimensions.");
            }
            else
                throw new NotImplementedException("");
        }
    }
 }
--- a/src/TensorFlowNET.Core/NumPy/NDArrayConverter.cs
+++ b/src/TensorFlowNET.Core/NumPy/NDArrayConverter.cs
@@ -10,6 +10,7 @@ namespace Tensorflow.NumPy
        public unsafe static T Scalar<T>(NDArray nd) where T : unmanaged
            => nd.dtype switch
            {
                TF_DataType.TF_BOOL => Scalar<T>(*(bool*)nd.data),
                TF_DataType.TF_UINT8 => Scalar<T>(*(byte*)nd.data),
                TF_DataType.TF_FLOAT => Scalar<T>(*(float*)nd.data),
                TF_DataType.TF_INT32 => Scalar<T>(*(int*)nd.data),
--- a/src/TensorFlowNET.Core/Numpy/Numpy.cs
+++ b/src/TensorFlowNET.Core/Numpy/Numpy.cs
@@ -43,7 +43,9 @@ public partial class np
    public static readonly TF_DataType @decimal = TF_DataType.TF_DOUBLE;
    public static readonly TF_DataType complex_ = TF_DataType.TF_COMPLEX;
    public static readonly TF_DataType complex64 = TF_DataType.TF_COMPLEX64;
    public static readonly TF_DataType complex128 = TF_DataType.TF_COMPLEX128; 
    public static readonly TF_DataType complex128 = TF_DataType.TF_COMPLEX128;
    public static readonly TF_DataType @string = TF_DataType.TF_STRING;
    public static readonly TF_DataType @object = TF_DataType.TF_VARIANT;
    #endregion
    public static double nan => double.NaN;
--- a/src/TensorFlowNET.Keras/Datasets/Imdb.cs
+++ b/src/TensorFlowNET.Keras/Datasets/Imdb.cs
@@ -70,7 +70,7 @@ namespace Tensorflow.Keras.Datasets
    public class Imdb
    {
        string origin_folder = "https://storage.googleapis.com/tensorflow/tf-keras-datasets/";
        string file_name = "imdb.npz";
        string file_name = "simple.npz";
        string dest_folder = "imdb";
        /// <summary>
        /// Loads the [IMDB dataset](https://ai.stanford.edu/~amaas/data/sentiment/).
@@ -128,13 +128,15 @@ namespace Tensorflow.Keras.Datasets
        (NDArray, NDArray) LoadX(byte[] bytes)
        {
            var y = np.Load_Npz<byte[]>(bytes);
            return (y["x_train.npy"], y["x_test.npy"]);
            var y = np.Load_Npz<int[,]>(bytes);
            var x_train = y["x_train.npy"];
            var x_test = y["x_test.npy"];
            return (x_train, x_test);
        }
        (NDArray, NDArray) LoadY(byte[] bytes)
        {
            var y = np.Load_Npz<long[]>(bytes);
            var y = np.Load_Npz<int[]>(bytes);
            return (y["y_train.npy"], y["y_test.npy"]);
        }