diff --git a/Numpy.NET.sln b/Numpy.NET.sln
index aca6f6a..a0a1c92 100644
--- a/Numpy.NET.sln
+++ b/Numpy.NET.sln
@@ -1,7 +1,7 @@
Microsoft Visual Studio Solution File, Format Version 12.00
-# Visual Studio Version 16
-VisualStudioVersion = 16.0.30503.244
+# Visual Studio Version 17
+VisualStudioVersion = 17.4.33103.184
MinimumVisualStudioVersion = 10.0.40219.1
Project("{9A19103F-16F7-4668-BE54-9A1E7A4F7556}") = "Numpy", "src\Numpy\Numpy.csproj", "{D527C885-AD64-4499-9E92-F9A543C0D14B}"
EndProject
@@ -35,7 +35,9 @@ Project("{9A19103F-16F7-4668-BE54-9A1E7A4F7556}") = "WebApiExample_netcore3.1",
EndProject
Project("{9A19103F-16F7-4668-BE54-9A1E7A4F7556}") = "CustomInstallLocationExample", "src\Examples\CustomInstallLocationExample\CustomInstallLocationExample.csproj", "{BB0A367A-8A36-454F-9F92-2FD6DA665A39}"
EndProject
-Project("{FAE04EC0-301F-11D3-BF4B-00C04F79EFBC}") = "SlicingExample", "src\Examples\SlicingExample\SlicingExample.csproj", "{FB116716-8C1F-4926-86F9-03AE46C7FA58}"
+Project("{9A19103F-16F7-4668-BE54-9A1E7A4F7556}") = "SlicingExample", "src\Examples\SlicingExample\SlicingExample.csproj", "{FB116716-8C1F-4926-86F9-03AE46C7FA58}"
+EndProject
+Project("{FAE04EC0-301F-11D3-BF4B-00C04F79EFBC}") = "WpfExample", "WpfExample\WpfExample.csproj", "{BF447620-877B-4000-BF75-527AEF94F347}"
EndProject
Global
GlobalSection(SolutionConfigurationPlatforms) = preSolution
@@ -107,6 +109,10 @@ Global
{FB116716-8C1F-4926-86F9-03AE46C7FA58}.Debug|Any CPU.Build.0 = Debug|Any CPU
{FB116716-8C1F-4926-86F9-03AE46C7FA58}.Release|Any CPU.ActiveCfg = Release|Any CPU
{FB116716-8C1F-4926-86F9-03AE46C7FA58}.Release|Any CPU.Build.0 = Release|Any CPU
+ {BF447620-877B-4000-BF75-527AEF94F347}.Debug|Any CPU.ActiveCfg = Debug|Any CPU
+ {BF447620-877B-4000-BF75-527AEF94F347}.Debug|Any CPU.Build.0 = Debug|Any CPU
+ {BF447620-877B-4000-BF75-527AEF94F347}.Release|Any CPU.ActiveCfg = Release|Any CPU
+ {BF447620-877B-4000-BF75-527AEF94F347}.Release|Any CPU.Build.0 = Release|Any CPU
EndGlobalSection
GlobalSection(SolutionProperties) = preSolution
HideSolutionNode = FALSE
@@ -119,6 +125,7 @@ Global
{53C73261-DD84-47D1-A9BA-E553D34FF0A3} = {25D84E98-E107-45C9-A0EC-0B25E24DA607}
{BB0A367A-8A36-454F-9F92-2FD6DA665A39} = {25D84E98-E107-45C9-A0EC-0B25E24DA607}
{FB116716-8C1F-4926-86F9-03AE46C7FA58} = {25D84E98-E107-45C9-A0EC-0B25E24DA607}
+ {BF447620-877B-4000-BF75-527AEF94F347} = {25D84E98-E107-45C9-A0EC-0B25E24DA607}
EndGlobalSection
GlobalSection(ExtensibilityGlobals) = postSolution
SolutionGuid = {5EB08541-5168-443C-B524-A5CB7E7C613D}
diff --git a/WpfExample/App.xaml b/WpfExample/App.xaml
new file mode 100644
index 0000000..8bcbf4d
--- /dev/null
+++ b/WpfExample/App.xaml
@@ -0,0 +1,9 @@
+
+
+
+
+
diff --git a/WpfExample/App.xaml.cs b/WpfExample/App.xaml.cs
new file mode 100644
index 0000000..66421cb
--- /dev/null
+++ b/WpfExample/App.xaml.cs
@@ -0,0 +1,16 @@
+using System;
+using System.Collections.Generic;
+using System.Configuration;
+using System.Data;
+using System.Linq;
+using System.Threading.Tasks;
+using System.Windows;
+
+namespace WpfExample
+{
+
+ public partial class App : Application
+ {
+
+ }
+}
diff --git a/WpfExample/AssemblyInfo.cs b/WpfExample/AssemblyInfo.cs
new file mode 100644
index 0000000..74087a1
--- /dev/null
+++ b/WpfExample/AssemblyInfo.cs
@@ -0,0 +1,10 @@
+using System.Windows;
+
+[assembly: ThemeInfo(
+ ResourceDictionaryLocation.None, //where theme specific resource dictionaries are located
+ //(used if a resource is not found in the page,
+ // or application resource dictionaries)
+ ResourceDictionaryLocation.SourceAssembly //where the generic resource dictionary is located
+ //(used if a resource is not found in the page,
+ // app, or any theme specific resource dictionaries)
+)]
diff --git a/WpfExample/MainWindow.xaml b/WpfExample/MainWindow.xaml
new file mode 100644
index 0000000..82bf2e4
--- /dev/null
+++ b/WpfExample/MainWindow.xaml
@@ -0,0 +1,17 @@
+
+
+
+
+
+ Run the blocking example first, then the non-blocking example will be activated.
+
+
+
+
diff --git a/WpfExample/MainWindow.xaml.cs b/WpfExample/MainWindow.xaml.cs
new file mode 100644
index 0000000..a5e2290
--- /dev/null
+++ b/WpfExample/MainWindow.xaml.cs
@@ -0,0 +1,88 @@
+using System;
+using System.Collections.Generic;
+using System.Diagnostics;
+using System.Linq;
+using System.Text;
+using System.Threading.Tasks;
+using System.Windows;
+using System.Windows.Controls;
+using System.Windows.Data;
+using System.Windows.Documents;
+using System.Windows.Input;
+using System.Windows.Media;
+using System.Windows.Media.Imaging;
+using System.Windows.Navigation;
+using System.Windows.Shapes;
+using Numpy;
+using Python.Runtime;
+
+namespace WpfExample
+{
+
+ public partial class MainWindow : Window
+ {
+ public MainWindow()
+ {
+ InitializeComponent();
+ }
+
+ private bool _allowThreads = false;
+
+ private void WriteLine(string text)
+ {
+ TextBox.AppendText(text + "\n");
+ TextBox.ScrollToEnd();
+ }
+
+ private void OnBlockingClick(object sender, RoutedEventArgs e)
+ {
+ WriteLine("Example 1: Matrix multiplication with NumPy on the GUI thread (blocking):");
+ // before starting the measurement, let us call numpy once to get the setup checks done.
+ np.arange(1);
+ var stopwatch = Stopwatch.StartNew();
+
+ var a1 = np.arange(60000).reshape(300, 200);
+ var a2 = np.arange(80000).reshape(200, 400);
+
+ var result = np.matmul(a1, a2);
+ stopwatch.Stop();
+
+ WriteLine($"execution time with NumPy: {stopwatch.Elapsed.TotalMilliseconds}ms\n");
+ WriteLine("Result:\n" + result.repr);
+ WriteLine("\nNote: blocking usage is not recommended. ");
+ WriteLine("\nIf you close the program without runnning example 2 it will hang indefinitely. ");
+ Button1.IsEnabled = false;
+ Button2.IsEnabled = true;
+ }
+
+ private async void OnNonBlockingClick(object sender, RoutedEventArgs e)
+ {
+ WriteLine("Example 2: Matrix multiplication with NumPy on a background thread (non-blocking):");
+
+ if (!_allowThreads) {
+ // https://github.com/pythonnet/pythonnet/issues/109
+ PythonEngine.BeginAllowThreads();
+ _allowThreads=true;
+ }
+ var stopwatch = Stopwatch.StartNew();
+ var resultString = "";
+ await Task.Run(() => {
+ using (Py.GIL()) {
+
+
+ var a1 = np.arange(60000).reshape(300, 200);
+ var a2 = np.arange(80000).reshape(200, 400);
+
+ var result = np.matmul(a1, a2);
+ stopwatch.Stop();
+ resultString = result.repr;
+ }
+ });
+ await this.Dispatcher.BeginInvoke(() => {
+ WriteLine($"execution time with NumPy: {stopwatch.Elapsed.TotalMilliseconds}ms\n");
+ WriteLine("Result:\n" + resultString);
+ });
+ WriteLine("\nNote: if you close the program now it will not hang because of PythonEngine.BeginAllowThreads();\nWe only have to make sure to enclose all calculations in using(Py.GIL()) { }");
+ }
+ }
+}
diff --git a/WpfExample/WpfExample.csproj b/WpfExample/WpfExample.csproj
new file mode 100644
index 0000000..475c825
--- /dev/null
+++ b/WpfExample/WpfExample.csproj
@@ -0,0 +1,14 @@
+
+
+
+ WinExe
+ net6.0-windows
+ enable
+ true
+
+
+
+
+
+
+
diff --git a/src/CodeMinion.ApiGenerator/NumPy/ApiGenerator.cs b/src/CodeMinion.ApiGenerator/NumPy/ApiGenerator.cs
index a1a525e..5709388 100644
--- a/src/CodeMinion.ApiGenerator/NumPy/ApiGenerator.cs
+++ b/src/CodeMinion.ApiGenerator/NumPy/ApiGenerator.cs
@@ -431,18 +431,17 @@ private void ParseNumpyDocPage(StaticApi api, string link, HtmlDoc html_doc, Tes
{
// do not add to NDArray instance methods
case "copyto":
- case "transpose":
- case "amax":
- case "amin":
- case "real":
- case "imag":
+ //case "transpose":
+ //case "amax":
+ //case "amin":
+ //case "real":
+ //case "imag":
continue;
}
-
- var dc = d.Clone();
- dc.Arguments.RemoveAt(0);
- //dc.ForwardToStaticImpl = "NumPy.Instance";
- ndarray_api.Declarations.Add(dc);
+ decl.IsExtensionFunction = true;
+ //var dc = d.Clone();
+ //dc.Arguments.RemoveAt(0);
+ //ndarray_api.Declarations.Add(dc);
}
}
@@ -1140,6 +1139,10 @@ private IEnumerable InferOverloads(Function decl)
yield break;
case "gradient": // don't generate.
yield break;
+ case "split":
+ yield return decl;
+ yield return decl.Clone(f => { f.Arguments[1].Type = "int"; });
+ yield break;
}
// without args we don't need to consider possible overloads
diff --git a/src/CodeMinion.Core/CodeGenerator.cs b/src/CodeMinion.Core/CodeGenerator.cs
index 900f9da..ab2017a 100644
--- a/src/CodeMinion.Core/CodeGenerator.cs
+++ b/src/CodeMinion.Core/CodeGenerator.cs
@@ -90,7 +90,7 @@ protected virtual void GenerateApiFunction(Declaration decl, CodeWriter s, bool
var prefix_str = "";
if (prefix && levels > 0)
prefix_str = string.Join("_", class_names.Skip(1)) + "_";
- s.Out($"public {(@static ? "static ":"")}{retval} {EscapeName(prefix_str + decl.Name)}{func.SharpOnlyPostfix}{generics}({arguments})");
+ s.Out($"public {(@static ? "static ":"")}{retval} {EscapeName(prefix_str + decl.Name)}{func.SharpOnlyPostfix}{generics}({(@static && func.IsExtensionFunction ? "this " : "")}{arguments})");
s.Block(() =>
{
GenerateFunctionBody(func, s, prefix_str);
@@ -596,7 +596,8 @@ public virtual void GenerateDynamicApi(DynamicApi api, CodeWriter s)
{
if (decl.ManualOverride || decl.Ignore)
continue;
- GenerateApiFunction(decl, s);
+ if (decl is Function && !(decl as Function).IsExtensionFunction)
+ GenerateApiFunction(decl, s);
}
catch (Exception e)
{
diff --git a/src/CodeMinion.Core/Models/Function.cs b/src/CodeMinion.Core/Models/Function.cs
index 75f3ffd..8525999 100644
--- a/src/CodeMinion.Core/Models/Function.cs
+++ b/src/CodeMinion.Core/Models/Function.cs
@@ -11,6 +11,11 @@ public class Function : Declaration
public bool IsConstructor { get; set; }
+ ///
+ /// Generate only the static function which also serves as an extension function
+ ///
+ public bool IsExtensionFunction { get; set; } = false;
+
///
/// Generic type parameters of the function
///
diff --git a/src/Examples/MatmulExample/MatmulExample.csproj b/src/Examples/MatmulExample/MatmulExample.csproj
index e308509..0e842bf 100644
--- a/src/Examples/MatmulExample/MatmulExample.csproj
+++ b/src/Examples/MatmulExample/MatmulExample.csproj
@@ -6,7 +6,7 @@
-
+
diff --git a/src/Numpy.Bare/Numpy.Bare.csproj b/src/Numpy.Bare/Numpy.Bare.csproj
index e0f2068..b1c5c8f 100644
--- a/src/Numpy.Bare/Numpy.Bare.csproj
+++ b/src/Numpy.Bare/Numpy.Bare.csproj
@@ -14,7 +14,7 @@
https://github.com/SciSharp/Numpy.NETData science, Machine Learning, AI, Scientific Computing, NumPy, Linear Algebra, FFT, SVD, Matrix, Pythonhttps://github.com/SciSharp/Numpy.NET/blob/master/LICENSE
- 3.7.1.28
+ 3.11.1.33https://github.com/SciSharp/Numpy.NET/blob/master/doc/img/numpy.net.icon128.png?raw=true3.7.1.4
@@ -86,8 +86,8 @@
-
-
+
+
diff --git a/src/Numpy/Manual/np.array.cs b/src/Numpy/Manual/np.array.cs
index c0388ff..b4348b6 100644
--- a/src/Numpy/Manual/np.array.cs
+++ b/src/Numpy/Manual/np.array.cs
@@ -62,6 +62,7 @@ public static NDarray array(T[] @object, Dtype dtype = null, bool? copy =
case short[] a: Marshal.Copy(a, 0, new IntPtr(ptr), a.Length); break;
case int[] a: Marshal.Copy(a, 0, new IntPtr(ptr), a.Length); break;
case long[] a: Marshal.Copy(a, 0, new IntPtr(ptr), a.Length); break;
+ //case Half[] a: Marshal.Copy(a, 0, new IntPtr(ptr), a.Length); break;
case float[] a: Marshal.Copy(a, 0, new IntPtr(ptr), a.Length); break;
case double[] a: Marshal.Copy(a, 0, new IntPtr(ptr), a.Length); break;
case bool[] a:
diff --git a/src/Numpy/Manual/np.math.cs b/src/Numpy/Manual/np.math.cs
index f19412e..9c75d80 100644
--- a/src/Numpy/Manual/np.math.cs
+++ b/src/Numpy/Manual/np.math.cs
@@ -1,6 +1,7 @@
using System;
using System.Collections.Generic;
using System.Linq;
+using System.Numerics;
using System.Runtime.InteropServices;
using System.Text;
using Numpy;
@@ -165,5 +166,97 @@ public static NDarray gradient(NDarray f, List varargs, int? edge_order
return ToCsharp(py);
}
+ ///
+ /// One-dimensional linear interpolation.
+ ///
+ /// Returns the one-dimensional piecewise linear interpolant to a function
+ /// with given discrete data points (xp, fp), evaluated at x.
+ ///
+ /// Notes
+ ///
+ /// Does not check that the x-coordinate sequence xp is increasing.
+ ///
+ /// If xp is not increasing, the results are nonsense.
+ ///
+ /// A simple check for increasing is:
+ ///
+ ///
+ /// The x-coordinates at which to evaluate the interpolated values.
+ ///
+ ///
+ /// The x-coordinates of the data points, must be increasing if argument
+ /// period is not specified.
+ /// Otherwise, xp is internally sorted after
+ /// normalizing the periodic boundaries with xp = xp % period.
+ ///
+ ///
+ /// The y-coordinates of the data points, same length as xp.
+ ///
+ ///
+ /// Value to return for x < xp[0], default is fp[0].
+ ///
+ ///
+ /// Value to return for x > xp[-1], default is fp[-1].
+ ///
+ ///
+ /// A period for the x-coordinates.
+ /// This parameter allows the proper
+ /// interpolation of angular x-coordinates.
+ /// Parameters left and right
+ /// are ignored if period is specified.
+ ///
+ ///
+ /// The interpolated values, same shape as x.
+ ///
+ public static NDarray interp(this NDarray x, IReadOnlyCollection xp, IReadOnlyCollection fp, float? left = null, float? right = null, float? period = null)
+ {
+ var __self__ = self;
+ var pyargs = ToTuple(new object[]
+ {
+ x,
+ xp,
+ fp,
+ });
+ var kwargs = new PyDict();
+ if (left != null) kwargs["left"] = ToPython(left);
+ if (right != null) kwargs["right"] = ToPython(right);
+ if (period != null) kwargs["period"] = ToPython(period);
+ dynamic py = __self__.InvokeMethod("interp", pyargs, kwargs);
+ return ToCsharp(py);
+ }
+
+ public static float interp(float x, IReadOnlyCollection xp, IReadOnlyCollection fp, float? left = null, float? right = null, float? period = null)
+ {
+ var __self__ = self;
+ var pyargs = ToTuple(new object[]
+ {
+ x,
+ xp,
+ fp,
+ });
+ var kwargs = new PyDict();
+ if (left != null) kwargs["left"] = ToPython(left);
+ if (right != null) kwargs["right"] = ToPython(right);
+ if (period != null) kwargs["period"] = ToPython(period);
+ dynamic py = __self__.InvokeMethod("interp", pyargs, kwargs);
+ return ToCsharp(py);
+ }
+
+ public static NDarray interp(this NDarray x, IReadOnlyCollection xp, Complex[] fp, Complex? left = null, Complex? right = null, float? period = null)
+ {
+ var __self__ = self;
+ var pyargs = ToTuple(new object[]
+ {
+ x,
+ xp,
+ np.array(fp),
+ });
+ var kwargs = new PyDict();
+ if (left != null) kwargs["left"] = ToPython(left);
+ if (right != null) kwargs["right"] = ToPython(right);
+ if (period != null) kwargs["period"] = ToPython(period);
+ dynamic py = __self__.InvokeMethod("interp", pyargs, kwargs);
+ return ToCsharp(py);
+ }
}
}
diff --git a/src/Numpy/Models/NDarray.Operators.cs b/src/Numpy/Models/NDarray.Operators.cs
index ad67654..b54d4e7 100644
--- a/src/Numpy/Models/NDarray.Operators.cs
+++ b/src/Numpy/Models/NDarray.Operators.cs
@@ -289,6 +289,14 @@ public NDarray pow(ValueType obj)
return new NDarray(a.self.InvokeMethod("__and__", obj.ToPython()));
}
+ ///
+ /// Return self&value.
+ ///
+ public static NDarray operator &(NDarray a, NDarray b)
+ {
+ return new NDarray(a.self.InvokeMethod("__and__", b.self));
+ }
+
///
/// Return self|value.
///
@@ -297,6 +305,14 @@ public NDarray pow(ValueType obj)
return new NDarray(a.self.InvokeMethod("__or__", obj.ToPython()));
}
+ ///
+ /// Return self|value.
+ ///
+ public static NDarray operator |(NDarray a, NDarray b)
+ {
+ return new NDarray(a.self.InvokeMethod("__or__", b.self));
+ }
+
///
/// Return self^value.
///
@@ -305,6 +321,14 @@ public NDarray pow(ValueType obj)
return new NDarray(a.self.InvokeMethod("__xor__", obj.ToPython()));
}
+ ///
+ /// Return self^value.
+ ///
+ public static NDarray operator ^(NDarray a, NDarray b)
+ {
+ return new NDarray(a.self.InvokeMethod("__xor__", b.self));
+ }
+
//------------------------------
// Arithmetic, in-place:
//------------------------------
diff --git a/src/Numpy/Models/NDarray.gen.cs b/src/Numpy/Models/NDarray.gen.cs
index 203b0e0..2bd1fa4 100644
--- a/src/Numpy/Models/NDarray.gen.cs
+++ b/src/Numpy/Models/NDarray.gen.cs
@@ -456,12593 +456,5 @@ public void __setstate__(int version, Shape shape, Dtype dtype, bool isFortran,
dynamic py = __self__.InvokeMethod("__setstate__", pyargs, kwargs);
}
- ///
- /// Gives a new shape to an array without changing its data.
- ///
- /// Notes
- ///
- /// It is not always possible to change the shape of an array without
- /// copying the data.
- /// If you want an error to be raised when the data is copied,
- /// you should assign the new shape to the shape attribute of the array:
- ///
- /// The order keyword gives the index ordering both for fetching the values
- /// from a, and then placing the values into the output array.
- ///
- /// For example, let’s say you have an array:
- ///
- /// You can think of reshaping as first raveling the array (using the given
- /// index order), then inserting the elements from the raveled array into the
- /// new array using the same kind of index ordering as was used for the
- /// raveling.
- ///
- ///
- /// The new shape should be compatible with the original shape.
- /// If
- /// an integer, then the result will be a 1-D array of that length.
- ///
- /// One shape dimension can be -1. In this case, the value is
- /// inferred from the length of the array and remaining dimensions.
- ///
- ///
- /// Read the elements of a using this index order, and place the
- /// elements into the reshaped array using this index order.
- /// ‘C’
- /// means to read / write the elements using C-like index order,
- /// with the last axis index changing fastest, back to the first
- /// axis index changing slowest.
- /// ‘F’ means to read / write the
- /// elements using Fortran-like index order, with the first index
- /// changing fastest, and the last index changing slowest.
- /// Note that
- /// the ‘C’ and ‘F’ options take no account of the memory layout of
- /// the underlying array, and only refer to the order of indexing.
- ///
- /// ‘A’ means to read / write the elements in Fortran-like index
- /// order if a is Fortran contiguous in memory, C-like order
- /// otherwise.
- ///
- ///
- /// This will be a new view object if possible; otherwise, it will
- /// be a copy.
- /// Note there is no guarantee of the memory layout (C- or
- /// Fortran- contiguous) of the returned array.
- ///
- public NDarray reshape(Shape newshape, string order = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- newshape,
- });
- var kwargs=new PyDict();
- if (order!=null) kwargs["order"]=ToPython(order);
- dynamic py = __self__.InvokeMethod("reshape", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return a contiguous flattened array.
- ///
- /// A 1-D array, containing the elements of the input, is returned.
- /// A copy is
- /// made only if needed.
- ///
- /// As of NumPy 1.10, the returned array will have the same type as the input
- /// array.
- /// (for example, a masked array will be returned for a masked array
- /// input)
- ///
- /// Notes
- ///
- /// In row-major, C-style order, in two dimensions, the row index
- /// varies the slowest, and the column index the quickest.
- /// This can
- /// be generalized to multiple dimensions, where row-major order
- /// implies that the index along the first axis varies slowest, and
- /// the index along the last quickest.
- /// The opposite holds for
- /// column-major, Fortran-style index ordering.
- ///
- /// When a view is desired in as many cases as possible, arr.reshape(-1)
- /// may be preferable.
- ///
- ///
- /// The elements of a are read using this index order.
- /// ‘C’ means
- /// to index the elements in row-major, C-style order,
- /// with the last axis index changing fastest, back to the first
- /// axis index changing slowest.
- /// ‘F’ means to index the elements
- /// in column-major, Fortran-style order, with the
- /// first index changing fastest, and the last index changing
- /// slowest.
- /// Note that the ‘C’ and ‘F’ options take no account of
- /// the memory layout of the underlying array, and only refer to
- /// the order of axis indexing.
- /// ‘A’ means to read the elements in
- /// Fortran-like index order if a is Fortran contiguous in
- /// memory, C-like order otherwise.
- /// ‘K’ means to read the
- /// elements in the order they occur in memory, except for
- /// reversing the data when strides are negative.
- /// By default, ‘C’
- /// index order is used.
- ///
- ///
- /// y is an array of the same subtype as a, with shape (a.size,).
- ///
- /// Note that matrices are special cased for backward compatibility, if a
- /// is a matrix, then y is a 1-D ndarray.
- ///
- public NDarray ravel(string order = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (order!=null) kwargs["order"]=ToPython(order);
- dynamic py = __self__.InvokeMethod("ravel", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Move axes of an array to new positions.
- ///
- /// Other axes remain in their original order.
- ///
- ///
- /// Original positions of the axes to move.
- /// These must be unique.
- ///
- ///
- /// Destination positions for each of the original axes.
- /// These must also be
- /// unique.
- ///
- ///
- /// Array with moved axes.
- /// This array is a view of the input array.
- ///
- public NDarray moveaxis(int[] source, int[] destination)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- source,
- destination,
- });
- var kwargs=new PyDict();
- dynamic py = __self__.InvokeMethod("moveaxis", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Roll the specified axis backwards, until it lies in a given position.
- ///
- /// This function continues to be supported for backward compatibility, but you
- /// should prefer moveaxis.
- /// The moveaxis function was added in NumPy
- /// 1.11.
- ///
- ///
- /// The axis to roll backwards.
- /// The positions of the other axes do not
- /// change relative to one another.
- ///
- ///
- /// The axis is rolled until it lies before this position.
- /// The default,
- /// 0, results in a “complete” roll.
- ///
- ///
- /// For NumPy >= 1.10.0 a view of a is always returned.
- /// For earlier
- /// NumPy versions a view of a is returned only if the order of the
- /// axes is changed, otherwise the input array is returned.
- ///
- public NDarray rollaxis(int axis, int? start = 0)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- axis,
- });
- var kwargs=new PyDict();
- if (start!=0) kwargs["start"]=ToPython(start);
- dynamic py = __self__.InvokeMethod("rollaxis", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Interchange two axes of an array.
- ///
- ///
- /// First axis.
- ///
- ///
- /// Second axis.
- ///
- ///
- /// For NumPy >= 1.10.0, if a is an ndarray, then a view of a is
- /// returned; otherwise a new array is created.
- /// For earlier NumPy
- /// versions a view of a is returned only if the order of the
- /// axes is changed, otherwise the input array is returned.
- ///
- public NDarray swapaxes(int axis1, int axis2)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- axis1,
- axis2,
- });
- var kwargs=new PyDict();
- dynamic py = __self__.InvokeMethod("swapaxes", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Produce an object that mimics broadcasting.
- ///
- ///
- /// Input parameters.
- ///
- ///
- /// Broadcast the input parameters against one another, and
- /// return an object that encapsulates the result.
- ///
- /// Amongst others, it has shape and nd properties, and
- /// may be used as an iterator.
- ///
- public NDarray broadcast(NDarray in1)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- in1,
- });
- var kwargs=new PyDict();
- dynamic py = __self__.InvokeMethod("broadcast", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Broadcast an array to a new shape.
- ///
- /// Notes
- ///
- ///
- /// The shape of the desired array.
- ///
- ///
- /// If True, then sub-classes will be passed-through, otherwise
- /// the returned array will be forced to be a base-class array (default).
- ///
- ///
- /// A readonly view on the original array with the given shape.
- /// It is
- /// typically not contiguous.
- /// Furthermore, more than one element of a
- /// broadcasted array may refer to a single memory location.
- ///
- public NDarray broadcast_to(Shape shape, bool? subok = false)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- shape,
- });
- var kwargs=new PyDict();
- if (subok!=false) kwargs["subok"]=ToPython(subok);
- dynamic py = __self__.InvokeMethod("broadcast_to", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Expand the shape of an array.
- ///
- /// Insert a new axis that will appear at the axis position in the expanded
- /// array shape.
- ///
- ///
- /// Position in the expanded axes where the new axis is placed.
- ///
- ///
- /// Output array.
- /// The number of dimensions is one greater than that of
- /// the input array.
- ///
- public NDarray expand_dims(int axis)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- axis,
- });
- var kwargs=new PyDict();
- dynamic py = __self__.InvokeMethod("expand_dims", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Remove single-dimensional entries from the shape of an array.
- ///
- ///
- /// Selects a subset of the single-dimensional entries in the
- /// shape.
- /// If an axis is selected with shape entry greater than
- /// one, an error is raised.
- ///
- ///
- /// The input array, but with all or a subset of the
- /// dimensions of length 1 removed.
- /// This is always a itself
- /// or a view into a.
- ///
- public NDarray squeeze(Axis axis = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- dynamic py = __self__.InvokeMethod("squeeze", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return an array converted to a float type.
- ///
- ///
- /// Float type code to coerce input array a.
- /// If dtype is one of the
- /// ‘int’ dtypes, it is replaced with float64.
- ///
- ///
- /// The input a as a float ndarray.
- ///
- public NDarray asfarray(Dtype dtype = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (dtype!=null) kwargs["dtype"]=ToPython(dtype);
- dynamic py = __self__.InvokeMethod("asfarray", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return an array (ndim >= 1) laid out in Fortran order in memory.
- ///
- ///
- /// By default, the data-type is inferred from the input data.
- ///
- ///
- /// The input a in Fortran, or column-major, order.
- ///
- public NDarray asfortranarray(Dtype dtype = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (dtype!=null) kwargs["dtype"]=ToPython(dtype);
- dynamic py = __self__.InvokeMethod("asfortranarray", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Convert the input to an array, checking for NaNs or Infs.
- ///
- ///
- /// By default, the data-type is inferred from the input data.
- ///
- ///
- /// Whether to use row-major (C-style) or
- /// column-major (Fortran-style) memory representation.
- ///
- /// Defaults to ‘C’.
- ///
- ///
- /// Array interpretation of a.
- /// No copy is performed if the input
- /// is already an ndarray.
- /// If a is a subclass of ndarray, a base
- /// class ndarray is returned.
- ///
- public NDarray asarray_chkfinite(Dtype dtype = null, string order = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (dtype!=null) kwargs["dtype"]=ToPython(dtype);
- if (order!=null) kwargs["order"]=ToPython(order);
- dynamic py = __self__.InvokeMethod("asarray_chkfinite", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return an ndarray of the provided type that satisfies requirements.
- ///
- /// This function is useful to be sure that an array with the correct flags
- /// is returned for passing to compiled code (perhaps through ctypes).
- ///
- /// Notes
- ///
- /// The returned array will be guaranteed to have the listed requirements
- /// by making a copy if needed.
- ///
- ///
- /// The required data-type.
- /// If None preserve the current dtype.
- /// If your
- /// application requires the data to be in native byteorder, include
- /// a byteorder specification as a part of the dtype specification.
- ///
- ///
- /// The requirements list can be any of the following
- ///
- public NDarray require(Dtype dtype, string[] requirements = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- dtype,
- });
- var kwargs=new PyDict();
- if (requirements!=null) kwargs["requirements"]=ToPython(requirements);
- dynamic py = __self__.InvokeMethod("require", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Split an array into multiple sub-arrays.
- ///
- ///
- /// If indices_or_sections is an integer, N, the array will be divided
- /// into N equal arrays along axis.
- /// If such a split is not possible,
- /// an error is raised.
- ///
- /// If indices_or_sections is a 1-D array of sorted integers, the entries
- /// indicate where along axis the array is split.
- /// For example,
- /// [2, 3] would, for axis=0, result in
- ///
- /// If an index exceeds the dimension of the array along axis,
- /// an empty sub-array is returned correspondingly.
- ///
- ///
- /// The axis along which to split, default is 0.
- ///
- ///
- /// A list of sub-arrays.
- ///
- public NDarray[] split(int[] indices_or_sections, int? axis = 0)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- indices_or_sections,
- });
- var kwargs=new PyDict();
- if (axis!=0) kwargs["axis"]=ToPython(axis);
- dynamic py = __self__.InvokeMethod("split", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Construct an array by repeating A the number of times given by reps.
- ///
- /// If reps has length d, the result will have dimension of
- /// max(d, A.ndim).
- ///
- /// If A.ndim < d, A is promoted to be d-dimensional by prepending new
- /// axes.
- /// So a shape (3,) array is promoted to (1, 3) for 2-D replication,
- /// or shape (1, 1, 3) for 3-D replication.
- /// If this is not the desired
- /// behavior, promote A to d-dimensions manually before calling this
- /// function.
- ///
- /// If A.ndim > d, reps is promoted to A.ndim by pre-pending 1’s to it.
- ///
- /// Thus for an A of shape (2, 3, 4, 5), a reps of (2, 2) is treated as
- /// (1, 1, 2, 2).
- ///
- /// Note : Although tile may be used for broadcasting, it is strongly
- /// recommended to use numpy’s broadcasting operations and functions.
- ///
- ///
- /// The number of repetitions of A along each axis.
- ///
- ///
- /// The tiled output array.
- ///
- public NDarray tile(NDarray reps)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- reps,
- });
- var kwargs=new PyDict();
- dynamic py = __self__.InvokeMethod("tile", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Repeat elements of an array.
- ///
- ///
- /// The number of repetitions for each element.
- /// repeats is broadcasted
- /// to fit the shape of the given axis.
- ///
- ///
- /// The axis along which to repeat values.
- /// By default, use the
- /// flattened input array, and return a flat output array.
- ///
- ///
- /// Output array which has the same shape as a, except along
- /// the given axis.
- ///
- public NDarray repeat(int[] repeats, int? axis = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- repeats,
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- dynamic py = __self__.InvokeMethod("repeat", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return a new array with sub-arrays along an axis deleted.
- /// For a one
- /// dimensional array, this returns those entries not returned by
- /// arr[obj].
- ///
- /// Notes
- ///
- /// Often it is preferable to use a boolean mask.
- /// For example:
- ///
- /// Is equivalent to np.delete(arr, [0,2,4], axis=0), but allows further
- /// use of mask.
- ///
- ///
- /// Indicate which sub-arrays to remove.
- ///
- ///
- /// The axis along which to delete the subarray defined by obj.
- ///
- /// If axis is None, obj is applied to the flattened array.
- ///
- ///
- /// A copy of arr with the elements specified by obj removed.
- /// Note
- /// that delete does not occur in-place.
- /// If axis is None, out is
- /// a flattened array.
- ///
- public NDarray delete(Slice obj, int? axis = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- obj,
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- dynamic py = __self__.InvokeMethod("delete", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Append values to the end of an array.
- ///
- ///
- /// These values are appended to a copy of arr.
- /// It must be of the
- /// correct shape (the same shape as arr, excluding axis).
- /// If
- /// axis is not specified, values can be any shape and will be
- /// flattened before use.
- ///
- ///
- /// The axis along which values are appended.
- /// If axis is not
- /// given, both arr and values are flattened before use.
- ///
- ///
- /// A copy of arr with values appended to axis.
- /// Note that
- /// append does not occur in-place: a new array is allocated and
- /// filled.
- /// If axis is None, out is a flattened array.
- ///
- public NDarray append(NDarray values, int? axis = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- values,
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- dynamic py = __self__.InvokeMethod("append", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Trim the leading and/or trailing zeros from a 1-D array or sequence.
- ///
- ///
- /// A string with ‘f’ representing trim from front and ‘b’ to trim from
- /// back.
- /// Default is ‘fb’, trim zeros from both front and back of the
- /// array.
- ///
- ///
- /// The result of trimming the input.
- /// The input data type is preserved.
- ///
- public NDarray trim_zeros(string trim = "fb")
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (trim!="fb") kwargs["trim"]=ToPython(trim);
- dynamic py = __self__.InvokeMethod("trim_zeros", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Find the unique elements of an array.
- ///
- /// Returns the sorted unique elements of an array.
- /// There are three optional
- /// outputs in addition to the unique elements:
- ///
- /// Notes
- ///
- /// When an axis is specified the subarrays indexed by the axis are sorted.
- ///
- /// This is done by making the specified axis the first dimension of the array
- /// and then flattening the subarrays in C order.
- /// The flattened subarrays are
- /// then viewed as a structured type with each element given a label, with the
- /// effect that we end up with a 1-D array of structured types that can be
- /// treated in the same way as any other 1-D array.
- /// The result is that the
- /// flattened subarrays are sorted in lexicographic order starting with the
- /// first element.
- ///
- ///
- /// The axis to operate on.
- /// If None, ar will be flattened.
- /// If an integer,
- /// the subarrays indexed by the given axis will be flattened and treated
- /// as the elements of a 1-D array with the dimension of the given axis,
- /// see the notes for more details.
- /// Object arrays or structured arrays
- /// that contain objects are not supported if the axis kwarg is used.
- /// The
- /// default is None.
- ///
- ///
- /// The sorted unique values.
- ///
- public NDarray unique(int? axis = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- dynamic py = __self__.InvokeMethod("unique", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Find the unique elements of an array.
- ///
- /// Returns the sorted unique elements of an array.
- /// There are three optional
- /// outputs in addition to the unique elements:
- ///
- /// Notes
- ///
- /// When an axis is specified the subarrays indexed by the axis are sorted.
- ///
- /// This is done by making the specified axis the first dimension of the array
- /// and then flattening the subarrays in C order.
- /// The flattened subarrays are
- /// then viewed as a structured type with each element given a label, with the
- /// effect that we end up with a 1-D array of structured types that can be
- /// treated in the same way as any other 1-D array.
- /// The result is that the
- /// flattened subarrays are sorted in lexicographic order starting with the
- /// first element.
- ///
- ///
- /// If True, also return the indices of ar (along the specified axis,
- /// if provided, or in the flattened array) that result in the unique array.
- ///
- ///
- /// If True, also return the indices of the unique array (for the specified
- /// axis, if provided) that can be used to reconstruct ar.
- ///
- ///
- /// If True, also return the number of times each unique item appears
- /// in ar.
- ///
- ///
- /// The axis to operate on.
- /// If None, ar will be flattened.
- /// If an integer,
- /// the subarrays indexed by the given axis will be flattened and treated
- /// as the elements of a 1-D array with the dimension of the given axis,
- /// see the notes for more details.
- /// Object arrays or structured arrays
- /// that contain objects are not supported if the axis kwarg is used.
- /// The
- /// default is None.
- ///
- ///
- /// The sorted unique values.
- ///
- public NDarray[] unique(bool return_index, bool return_inverse, bool return_counts, int? axis = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (return_index!=null) kwargs["return_index"]=ToPython(return_index);
- if (return_inverse!=null) kwargs["return_inverse"]=ToPython(return_inverse);
- if (return_counts!=null) kwargs["return_counts"]=ToPython(return_counts);
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- dynamic py = __self__.InvokeMethod("unique", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Reverse the order of elements in an array along the given axis.
- ///
- /// The shape of the array is preserved, but the elements are reordered.
- ///
- /// Notes
- ///
- /// flip(m, 0) is equivalent to flipud(m).
- ///
- /// flip(m, 1) is equivalent to fliplr(m).
- ///
- /// flip(m, n) corresponds to m[...,::-1,...] with ::-1 at position n.
- ///
- /// flip(m) corresponds to m[::-1,::-1,...,::-1] with ::-1 at all
- /// positions.
- ///
- /// flip(m, (0, 1)) corresponds to m[::-1,::-1,...] with ::-1 at
- /// position 0 and position 1.
- ///
- ///
- /// Axis or axes along which to flip over.
- /// The default,
- /// axis=None, will flip over all of the axes of the input array.
- ///
- /// If axis is negative it counts from the last to the first axis.
- ///
- /// If axis is a tuple of ints, flipping is performed on all of the axes
- /// specified in the tuple.
- ///
- ///
- /// A view of m with the entries of axis reversed.
- /// Since a view is
- /// returned, this operation is done in constant time.
- ///
- public NDarray flip(Axis axis = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- dynamic py = __self__.InvokeMethod("flip", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Flip array in the left/right direction.
- ///
- /// Flip the entries in each row in the left/right direction.
- ///
- /// Columns are preserved, but appear in a different order than before.
- ///
- /// Notes
- ///
- /// Equivalent to m[:,::-1].
- /// Requires the array to be at least 2-D.
- ///
- ///
- /// A view of m with the columns reversed.
- /// Since a view
- /// is returned, this operation is .
- ///
- public NDarray fliplr()
- {
- //auto-generated code, do not change
- var __self__=self;
- dynamic py = __self__.InvokeMethod("fliplr");
- return ToCsharp(py);
- }
-
- ///
- /// Flip array in the up/down direction.
- ///
- /// Flip the entries in each column in the up/down direction.
- ///
- /// Rows are preserved, but appear in a different order than before.
- ///
- /// Notes
- ///
- /// Equivalent to m[::-1,...].
- ///
- /// Does not require the array to be two-dimensional.
- ///
- ///
- /// A view of m with the rows reversed.
- /// Since a view is
- /// returned, this operation is .
- ///
- public NDarray flipud()
- {
- //auto-generated code, do not change
- var __self__=self;
- dynamic py = __self__.InvokeMethod("flipud");
- return ToCsharp(py);
- }
-
- ///
- /// Roll array elements along a given axis.
- ///
- /// Elements that roll beyond the last position are re-introduced at
- /// the first.
- ///
- /// Notes
- ///
- /// Supports rolling over multiple dimensions simultaneously.
- ///
- ///
- /// The number of places by which elements are shifted.
- /// If a tuple,
- /// then axis must be a tuple of the same size, and each of the
- /// given axes is shifted by the corresponding number.
- /// If an int
- /// while axis is a tuple of ints, then the same value is used for
- /// all given axes.
- ///
- ///
- /// Axis or axes along which elements are shifted.
- /// By default, the
- /// array is flattened before shifting, after which the original
- /// shape is restored.
- ///
- ///
- /// Output array, with the same shape as a.
- ///
- public NDarray roll(int[] shift, Axis axis = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- shift,
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- dynamic py = __self__.InvokeMethod("roll", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Rotate an array by 90 degrees in the plane specified by axes.
- ///
- /// Rotation direction is from the first towards the second axis.
- ///
- /// Notes
- ///
- /// rot90(m, k=1, axes=(1,0)) is the reverse of rot90(m, k=1, axes=(0,1))
- /// rot90(m, k=1, axes=(1,0)) is equivalent to rot90(m, k=-1, axes=(0,1))
- ///
- ///
- /// Number of times the array is rotated by 90 degrees.
- ///
- ///
- /// The array is rotated in the plane defined by the axes.
- ///
- /// Axes must be different.
- ///
- ///
- /// A rotated view of m.
- ///
- public NDarray rot90(int k = 1, int[] axes = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (k!=1) kwargs["k"]=ToPython(k);
- if (axes!=null) kwargs["axes"]=ToPython(axes);
- dynamic py = __self__.InvokeMethod("rot90", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Compute the bit-wise AND of two arrays element-wise.
- ///
- /// Computes the bit-wise AND of the underlying binary representation of
- /// the integers in the input arrays.
- /// This ufunc implements the C/Python
- /// operator &.
- ///
- ///
- /// Only integer and boolean types are handled.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Result.
- ///
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray bitwise_and(NDarray x1, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x1,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("bitwise_and", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Compute the bit-wise OR of two arrays element-wise.
- ///
- /// Computes the bit-wise OR of the underlying binary representation of
- /// the integers in the input arrays.
- /// This ufunc implements the C/Python
- /// operator |.
- ///
- ///
- /// Only integer and boolean types are handled.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Result.
- ///
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray bitwise_or(NDarray x1, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x1,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("bitwise_or", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Compute the bit-wise XOR of two arrays element-wise.
- ///
- /// Computes the bit-wise XOR of the underlying binary representation of
- /// the integers in the input arrays.
- /// This ufunc implements the C/Python
- /// operator ^.
- ///
- ///
- /// Only integer and boolean types are handled.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Result.
- ///
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray bitwise_xor(NDarray x1, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x1,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("bitwise_xor", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Compute bit-wise inversion, or bit-wise NOT, element-wise.
- ///
- /// Computes the bit-wise NOT of the underlying binary representation of
- /// the integers in the input arrays.
- /// This ufunc implements the C/Python
- /// operator ~.
- ///
- /// For signed integer inputs, the two’s complement is returned.
- /// In a
- /// two’s-complement system negative numbers are represented by the two’s
- /// complement of the absolute value.
- /// This is the most common method of
- /// representing signed integers on computers [1].
- /// A N-bit
- /// two’s-complement system can represent every integer in the range
- /// to .
- ///
- /// Notes
- ///
- /// bitwise_not is an alias for invert:
- ///
- /// References
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Result.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray invert(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("invert", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Shift the bits of an integer to the right.
- ///
- /// Bits are shifted to the right x2. Because the internal
- /// representation of numbers is in binary format, this operation is
- /// equivalent to dividing x1 by 2**x2.
- ///
- ///
- /// Number of bits to remove at the right of x1.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Return x1 with bits shifted x2 times to the right.
- ///
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray right_shift(NDarray x2, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x2,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("right_shift", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Packs the elements of a binary-valued array into bits in a uint8 array.
- ///
- /// The result is padded to full bytes by inserting zero bits at the end.
- ///
- ///
- /// The dimension over which bit-packing is done.
- ///
- /// None implies packing the flattened array.
- ///
- ///
- /// Array of type uint8 whose elements represent bits corresponding to the
- /// logical (0 or nonzero) value of the input elements.
- /// The shape of
- /// packed has the same number of dimensions as the input (unless axis
- /// is None, in which case the output is 1-D).
- ///
- public NDarray packbits(int? axis = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- dynamic py = __self__.InvokeMethod("packbits", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Unpacks elements of a uint8 array into a binary-valued output array.
- ///
- /// Each element of myarray represents a bit-field that should be unpacked
- /// into a binary-valued output array.
- /// The shape of the output array is either
- /// 1-D (if axis is None) or the same shape as the input array with unpacking
- /// done along the axis specified.
- ///
- ///
- /// The dimension over which bit-unpacking is done.
- ///
- /// None implies unpacking the flattened array.
- ///
- ///
- /// The elements are binary-valued (0 or 1).
- ///
- public NDarray unpackbits(int? axis = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- dynamic py = __self__.InvokeMethod("unpackbits", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// For scalar a, returns the data type with the smallest size
- /// and smallest scalar kind which can hold its value.
- /// For non-scalar
- /// array a, returns the vector’s dtype unmodified.
- ///
- /// Floating point values are not demoted to integers,
- /// and complex values are not demoted to floats.
- ///
- /// Notes
- ///
- ///
- /// The minimal data type.
- ///
- public Dtype min_scalar_type()
- {
- //auto-generated code, do not change
- var __self__=self;
- dynamic py = __self__.InvokeMethod("min_scalar_type");
- return ToCsharp(py);
- }
-
- ///
- /// Return a scalar type which is common to the input arrays.
- ///
- /// The return type will always be an inexact (i.e.
- /// floating point) scalar
- /// type, even if all the arrays are integer arrays.
- /// If one of the inputs is
- /// an integer array, the minimum precision type that is returned is a
- /// 64-bit floating point dtype.
- ///
- /// All input arrays except int64 and uint64 can be safely cast to the
- /// returned dtype without loss of information.
- ///
- ///
- /// Input arrays.
- ///
- ///
- /// Data type code.
- ///
- public Dtype common_type(NDarray array1)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- array1,
- });
- var kwargs=new PyDict();
- dynamic py = __self__.InvokeMethod("common_type", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Modified Bessel function of the first kind, order 0.
- ///
- /// Usually denoted . This function does broadcast, but will not
- /// “up-cast” int dtype arguments unless accompanied by at least one float or
- /// complex dtype argument (see Raises below).
- ///
- /// Notes
- ///
- /// We use the algorithm published by Clenshaw [1] and referenced by
- /// Abramowitz and Stegun [2], for which the function domain is
- /// partitioned into the two intervals [0,8] and (8,inf), and Chebyshev
- /// polynomial expansions are employed in each interval.
- /// Relative error on
- /// the domain [0,30] using IEEE arithmetic is documented [3] as having a
- /// peak of 5.8e-16 with an rms of 1.4e-16 (n = 30000).
- ///
- /// References
- ///
- ///
- /// The modified Bessel function evaluated at each of the elements of x.
- ///
- public NDarray i0()
- {
- //auto-generated code, do not change
- var __self__=self;
- dynamic py = __self__.InvokeMethod("i0");
- return ToCsharp(py);
- }
-
- ///
- /// Compute the future value.
- ///
- /// Notes
- ///
- /// The future value is computed by solving the equation:
- ///
- /// or, when rate == 0:
- ///
- /// References
- ///
- ///
- /// Number of compounding periods
- ///
- ///
- /// Payment
- ///
- ///
- /// Present value
- ///
- ///
- /// When payments are due (‘begin’ (1) or ‘end’ (0)).
- ///
- /// Defaults to {‘end’, 0}.
- ///
- ///
- /// Future values.
- /// If all input is scalar, returns a scalar float.
- /// If
- /// any input is array_like, returns future values for each input element.
- ///
- /// If multiple inputs are array_like, they all must have the same shape.
- ///
- public NDarray fv(NDarray nper, NDarray pmt, NDarray pv, string @when = "end")
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- nper,
- pmt,
- pv,
- });
- var kwargs=new PyDict();
- if (@when!="end") kwargs["when"]=ToPython(@when);
- dynamic py = __self__.InvokeMethod("fv", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Compute the present value.
- ///
- /// Notes
- ///
- /// The present value is computed by solving the equation:
- ///
- /// or, when rate = 0:
- ///
- /// for pv, which is then returned.
- ///
- /// References
- ///
- ///
- /// Number of compounding periods
- ///
- ///
- /// Payment
- ///
- ///
- /// Future value
- ///
- ///
- /// When payments are due (‘begin’ (1) or ‘end’ (0))
- ///
- ///
- /// Present value of a series of payments or investments.
- ///
- public NDarray pv(NDarray nper, NDarray pmt, NDarray fv = null, string @when = "end")
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- nper,
- pmt,
- });
- var kwargs=new PyDict();
- if (fv!=null) kwargs["fv"]=ToPython(fv);
- if (@when!="end") kwargs["when"]=ToPython(@when);
- dynamic py = __self__.InvokeMethod("pv", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Compute the payment against loan principal plus interest.
- ///
- /// Notes
- ///
- /// The payment is computed by solving the equation:
- ///
- /// or, when rate == 0:
- ///
- /// for pmt.
- ///
- /// Note that computing a monthly mortgage payment is only
- /// one use for this function.
- /// For example, pmt returns the
- /// periodic deposit one must make to achieve a specified
- /// future balance given an initial deposit, a fixed,
- /// periodically compounded interest rate, and the total
- /// number of periods.
- ///
- /// References
- ///
- ///
- /// Number of compounding periods
- ///
- ///
- /// Present value
- ///
- ///
- /// Future value (default = 0)
- ///
- ///
- /// When payments are due (‘begin’ (1) or ‘end’ (0))
- ///
- ///
- /// Payment against loan plus interest.
- /// If all input is scalar, returns a
- /// scalar float.
- /// If any input is array_like, returns payment for each
- /// input element.
- /// If multiple inputs are array_like, they all must have
- /// the same shape.
- ///
- public NDarray pmt(NDarray nper, NDarray pv, NDarray fv = null, string @when = "end")
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- nper,
- pv,
- });
- var kwargs=new PyDict();
- if (fv!=null) kwargs["fv"]=ToPython(fv);
- if (@when!="end") kwargs["when"]=ToPython(@when);
- dynamic py = __self__.InvokeMethod("pmt", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Compute the payment against loan principal.
- ///
- ///
- /// Amount paid against the loan changes.
- /// The per is the period of
- /// interest.
- ///
- ///
- /// Number of compounding periods
- ///
- ///
- /// Present value
- ///
- ///
- /// Future value
- ///
- ///
- /// When payments are due (‘begin’ (1) or ‘end’ (0))
- ///
- public void ppmt(NDarray per, NDarray nper, NDarray pv, NDarray fv = null, string @when = "end")
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- per,
- nper,
- pv,
- });
- var kwargs=new PyDict();
- if (fv!=null) kwargs["fv"]=ToPython(fv);
- if (@when!="end") kwargs["when"]=ToPython(@when);
- dynamic py = __self__.InvokeMethod("ppmt", pyargs, kwargs);
- }
-
- ///
- /// Compute the interest portion of a payment.
- ///
- /// Notes
- ///
- /// The total payment is made up of payment against principal plus interest.
- ///
- /// pmt = ppmt + ipmt
- ///
- ///
- /// Interest paid against the loan changes during the life or the loan.
- ///
- /// The per is the payment period to calculate the interest amount.
- ///
- ///
- /// Number of compounding periods
- ///
- ///
- /// Present value
- ///
- ///
- /// Future value
- ///
- ///
- /// When payments are due (‘begin’ (1) or ‘end’ (0)).
- ///
- /// Defaults to {‘end’, 0}.
- ///
- ///
- /// Interest portion of payment.
- /// If all input is scalar, returns a scalar
- /// float.
- /// If any input is array_like, returns interest payment for each
- /// input element.
- /// If multiple inputs are array_like, they all must have
- /// the same shape.
- ///
- public NDarray ipmt(NDarray per, NDarray nper, NDarray pv, NDarray fv = null, string @when = "end")
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- per,
- nper,
- pv,
- });
- var kwargs=new PyDict();
- if (fv!=null) kwargs["fv"]=ToPython(fv);
- if (@when!="end") kwargs["when"]=ToPython(@when);
- dynamic py = __self__.InvokeMethod("ipmt", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the Internal Rate of Return (IRR).
- ///
- /// This is the “average” periodically compounded rate of return
- /// that gives a net present value of 0.0; for a more complete explanation,
- /// see Notes below.
- ///
- /// decimal.Decimal type is not supported.
- ///
- /// Notes
- ///
- /// The IRR is perhaps best understood through an example (illustrated
- /// using np.irr in the Examples section below).
- /// Suppose one invests 100
- /// units and then makes the following withdrawals at regular (fixed)
- /// intervals: 39, 59, 55, 20. Assuming the ending value is 0, one’s 100
- /// unit investment yields 173 units; however, due to the combination of
- /// compounding and the periodic withdrawals, the “average” rate of return
- /// is neither simply 0.73/4 nor (1.73)^0.25-1. Rather, it is the solution
- /// (for ) of the equation:
- ///
- /// In general, for values ,
- /// irr is the solution of the equation: [G]
- ///
- /// References
- ///
- ///
- /// Internal Rate of Return for periodic input values.
- ///
- public float irr()
- {
- //auto-generated code, do not change
- var __self__=self;
- dynamic py = __self__.InvokeMethod("irr");
- return ToCsharp(py);
- }
-
- ///
- /// Modified internal rate of return.
- ///
- ///
- /// Interest rate paid on the cash flows
- ///
- ///
- /// Interest rate received on the cash flows upon reinvestment
- ///
- ///
- /// Modified internal rate of return
- ///
- public float mirr(ValueType finance_rate, ValueType reinvest_rate)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- finance_rate,
- reinvest_rate,
- });
- var kwargs=new PyDict();
- dynamic py = __self__.InvokeMethod("mirr", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Compute the number of periodic payments.
- ///
- /// decimal.Decimal type is not supported.
- ///
- /// Notes
- ///
- /// The number of periods nper is computed by solving the equation:
- ///
- /// but if rate = 0 then:
- ///
- ///
- /// Payment
- ///
- ///
- /// Present value
- ///
- ///
- /// Future value
- ///
- ///
- /// When payments are due (‘begin’ (1) or ‘end’ (0))
- ///
- public void nper(NDarray pmt, NDarray pv, NDarray fv = null, string @when = "end")
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- pmt,
- pv,
- });
- var kwargs=new PyDict();
- if (fv!=null) kwargs["fv"]=ToPython(fv);
- if (@when!="end") kwargs["when"]=ToPython(@when);
- dynamic py = __self__.InvokeMethod("nper", pyargs, kwargs);
- }
-
- ///
- /// Compute the rate of interest per period.
- ///
- /// Notes
- ///
- /// The rate of interest is computed by iteratively solving the
- /// (non-linear) equation:
- ///
- /// for rate.
- ///
- /// References
- ///
- /// Wheeler, D.
- /// A., E.
- /// Rathke, and R.
- /// Weir (Eds.) (2009, May).
- /// Open Document
- /// Format for Office Applications (OpenDocument)v1.2, Part 2: Recalculated
- /// Formula (OpenFormula) Format - Annotated Version, Pre-Draft 12.
- /// Organization for the Advancement of Structured Information Standards
- /// (OASIS).
- /// Billerica, MA, USA.
- /// [ODT Document].
- /// Available:
- /// http://www.oasis-open.org/committees/documents.php?wg_abbrev=office-formula
- /// OpenDocument-formula-20090508.odt
- ///
- ///
- /// Payment
- ///
- ///
- /// Present value
- ///
- ///
- /// Future value
- ///
- ///
- /// When payments are due (‘begin’ (1) or ‘end’ (0))
- ///
- ///
- /// Starting guess for solving the rate of interest, default 0.1
- ///
- ///
- /// Required tolerance for the solution, default 1e-6
- ///
- ///
- /// Maximum iterations in finding the solution
- ///
- public void rate(NDarray pmt, NDarray pv, NDarray fv, string @when = "end", double? guess = null, double? tol = null, int? maxiter = 100)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- pmt,
- pv,
- fv,
- });
- var kwargs=new PyDict();
- if (@when!="end") kwargs["when"]=ToPython(@when);
- if (guess!=null) kwargs["guess"]=ToPython(guess);
- if (tol!=null) kwargs["tol"]=ToPython(tol);
- if (maxiter!=100) kwargs["maxiter"]=ToPython(maxiter);
- dynamic py = __self__.InvokeMethod("rate", pyargs, kwargs);
- }
-
- ///
- /// Return the indices of the elements that are non-zero.
- ///
- /// Returns a tuple of arrays, one for each dimension of a,
- /// containing the indices of the non-zero elements in that
- /// dimension.
- /// The values in a are always tested and returned in
- /// row-major, C-style order.
- /// The corresponding non-zero
- /// values can be obtained with:
- ///
- /// To group the indices by element, rather than dimension, use:
- ///
- /// The result of this is always a 2-D array, with a row for
- /// each non-zero element.
- ///
- ///
- /// Indices of elements that are non-zero.
- ///
- public NDarray[] nonzero()
- {
- //auto-generated code, do not change
- var __self__=self;
- dynamic py = __self__.InvokeMethod("nonzero");
- return ToCsharp(py);
- }
-
- ///
- /// Return elements chosen from x or y depending on condition.
- ///
- /// Notes
- ///
- /// If all the arrays are 1-D, where is equivalent to:
- ///
- ///
- /// Values from which to choose.
- /// x, y and condition need to be
- /// broadcastable to some shape.
- ///
- ///
- /// Values from which to choose.
- /// x, y and condition need to be
- /// broadcastable to some shape.
- ///
- ///
- /// An array with elements from x where condition is True, and elements
- /// from y elsewhere.
- ///
- public NDarray @where(NDarray y, NDarray x)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- y,
- x,
- });
- var kwargs=new PyDict();
- dynamic py = __self__.InvokeMethod("where", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return elements chosen from x or y depending on condition.
- ///
- /// Notes
- ///
- /// If all the arrays are 1-D, where is equivalent to:
- ///
- ///
- /// An array with elements from x where condition is True, and elements
- /// from y elsewhere.
- ///
- public NDarray[] @where()
- {
- //auto-generated code, do not change
- var __self__=self;
- dynamic py = __self__.InvokeMethod("where");
- return ToCsharp(py);
- }
-
- ///
- /// Converts a flat index or array of flat indices into a tuple
- /// of coordinate arrays.
- ///
- ///
- /// The shape of the array to use for unraveling indices.
- ///
- ///
- /// Determines whether the indices should be viewed as indexing in
- /// row-major (C-style) or column-major (Fortran-style) order.
- ///
- ///
- /// Each array in the tuple has the same shape as the indices
- /// array.
- ///
- public NDarray[] unravel_index(Shape shape, string order = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- shape,
- });
- var kwargs=new PyDict();
- if (order!=null) kwargs["order"]=ToPython(order);
- dynamic py = __self__.InvokeMethod("unravel_index", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the indices to access the main diagonal of an n-dimensional array.
- ///
- /// See diag_indices for full details.
- ///
- /// Notes
- ///
- public void diag_indices_from()
- {
- //auto-generated code, do not change
- var __self__=self;
- dynamic py = __self__.InvokeMethod("diag_indices_from");
- }
-
- ///
- /// Return the indices for the lower-triangle of arr.
- ///
- /// See tril_indices for full details.
- ///
- /// Notes
- ///
- ///
- /// Diagonal offset (see tril for details).
- ///
- public void tril_indices_from(int? k = 0)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (k!=0) kwargs["k"]=ToPython(k);
- dynamic py = __self__.InvokeMethod("tril_indices_from", pyargs, kwargs);
- }
-
- ///
- /// Return the indices for the upper-triangle of arr.
- ///
- /// See triu_indices for full details.
- ///
- /// Notes
- ///
- ///
- /// Diagonal offset (see triu for details).
- ///
- ///
- /// Indices for the upper-triangle of arr.
- ///
- public NDarray[] triu_indices_from(int? k = 0)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (k!=0) kwargs["k"]=ToPython(k);
- dynamic py = __self__.InvokeMethod("triu_indices_from", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Take values from the input array by matching 1d index and data slices.
- ///
- /// This iterates over matching 1d slices oriented along the specified axis in
- /// the index and data arrays, and uses the former to look up values in the
- /// latter.
- /// These slices can be different lengths.
- ///
- /// Functions returning an index along an axis, like argsort and
- /// argpartition, produce suitable indices for this function.
- ///
- /// Notes
- ///
- /// This is equivalent to (but faster than) the following use of ndindex and
- /// s_, which sets each of ii and kk to a tuple of indices:
- ///
- /// Equivalently, eliminating the inner loop, the last two lines would be:
- ///
- ///
- /// Indices to take along each 1d slice of arr.
- /// This must match the
- /// dimension of arr, but dimensions Ni and Nj only need to broadcast
- /// against arr.
- ///
- ///
- /// The axis to take 1d slices along.
- /// If axis is None, the input array is
- /// treated as if it had first been flattened to 1d, for consistency with
- /// sort and argsort.
- ///
- public NDarray take_along_axis(NDarray indices, int? axis = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- indices,
- axis,
- });
- var kwargs=new PyDict();
- dynamic py = __self__.InvokeMethod("take_along_axis", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return specified diagonals.
- ///
- /// If a is 2-D, returns the diagonal of a with the given offset,
- /// i.e., the collection of elements of the form a[i, i+offset].
- /// If
- /// a has more than two dimensions, then the axes specified by axis1
- /// and axis2 are used to determine the 2-D sub-array whose diagonal is
- /// returned.
- /// The shape of the resulting array can be determined by
- /// removing axis1 and axis2 and appending an index to the right equal
- /// to the size of the resulting diagonals.
- ///
- /// In versions of NumPy prior to 1.7, this function always returned a new,
- /// independent array containing a copy of the values in the diagonal.
- ///
- /// In NumPy 1.7 and 1.8, it continues to return a copy of the diagonal,
- /// but depending on this fact is deprecated.
- /// Writing to the resulting
- /// array continues to work as it used to, but a FutureWarning is issued.
- ///
- /// Starting in NumPy 1.9 it returns a read-only view on the original array.
- ///
- /// Attempting to write to the resulting array will produce an error.
- ///
- /// In some future release, it will return a read/write view and writing to
- /// the returned array will alter your original array.
- /// The returned array
- /// will have the same type as the input array.
- ///
- /// If you don’t write to the array returned by this function, then you can
- /// just ignore all of the above.
- ///
- /// If you depend on the current behavior, then we suggest copying the
- /// returned array explicitly, i.e., use np.diagonal(a).copy() instead
- /// of just np.diagonal(a).
- /// This will work with both past and future
- /// versions of NumPy.
- ///
- ///
- /// Offset of the diagonal from the main diagonal.
- /// Can be positive or
- /// negative.
- /// Defaults to main diagonal (0).
- ///
- ///
- /// Axis to be used as the first axis of the 2-D sub-arrays from which
- /// the diagonals should be taken.
- /// Defaults to first axis (0).
- ///
- ///
- /// Axis to be used as the second axis of the 2-D sub-arrays from
- /// which the diagonals should be taken.
- /// Defaults to second axis (1).
- ///
- ///
- /// If a is 2-D, then a 1-D array containing the diagonal and of the
- /// same type as a is returned unless a is a matrix, in which case
- /// a 1-D array rather than a (2-D) matrix is returned in order to
- /// maintain backward compatibility.
- ///
- /// If a.ndim > 2, then the dimensions specified by axis1 and axis2
- /// are removed, and a new axis inserted at the end corresponding to the
- /// diagonal.
- ///
- public NDarray diagonal(int? offset = 0, int? axis1 = 0, int? axis2 = 1)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (offset!=0) kwargs["offset"]=ToPython(offset);
- if (axis1!=0) kwargs["axis1"]=ToPython(axis1);
- if (axis2!=1) kwargs["axis2"]=ToPython(axis2);
- dynamic py = __self__.InvokeMethod("diagonal", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Change elements of an array based on conditional and input values.
- ///
- /// Similar to np.copyto(arr, vals, where=mask), the difference is that
- /// place uses the first N elements of vals, where N is the number of
- /// True values in mask, while copyto uses the elements where mask
- /// is True.
- ///
- /// Note that extract does the exact opposite of place.
- ///
- ///
- /// Boolean mask array.
- /// Must have the same size as a.
- ///
- ///
- /// Values to put into a.
- /// Only the first N elements are used, where
- /// N is the number of True values in mask.
- /// If vals is smaller
- /// than N, it will be repeated, and if elements of a are to be masked,
- /// this sequence must be non-empty.
- ///
- public void place(NDarray mask, NDarray vals)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- mask,
- vals,
- });
- var kwargs=new PyDict();
- dynamic py = __self__.InvokeMethod("place", pyargs, kwargs);
- }
-
- ///
- /// Replaces specified elements of an array with given values.
- ///
- /// The indexing works on the flattened target array.
- /// put is roughly
- /// equivalent to:
- ///
- ///
- /// Target indices, interpreted as integers.
- ///
- ///
- /// Values to place in a at target indices.
- /// If v is shorter than
- /// ind it will be repeated as necessary.
- ///
- ///
- /// Specifies how out-of-bounds indices will behave.
- ///
- /// ‘clip’ mode means that all indices that are too large are replaced
- /// by the index that addresses the last element along that axis.
- /// Note
- /// that this disables indexing with negative numbers.
- ///
- public void put(NDarray ind, NDarray v, string mode = "raise")
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- ind,
- v,
- });
- var kwargs=new PyDict();
- if (mode!="raise") kwargs["mode"]=ToPython(mode);
- dynamic py = __self__.InvokeMethod("put", pyargs, kwargs);
- }
-
- ///
- /// Put values into the destination array by matching 1d index and data slices.
- ///
- /// This iterates over matching 1d slices oriented along the specified axis in
- /// the index and data arrays, and uses the former to place values into the
- /// latter.
- /// These slices can be different lengths.
- ///
- /// Functions returning an index along an axis, like argsort and
- /// argpartition, produce suitable indices for this function.
- ///
- /// Notes
- ///
- /// This is equivalent to (but faster than) the following use of ndindex and
- /// s_, which sets each of ii and kk to a tuple of indices:
- ///
- /// Equivalently, eliminating the inner loop, the last two lines would be:
- ///
- ///
- /// Indices to change along each 1d slice of arr.
- /// This must match the
- /// dimension of arr, but dimensions in Ni and Nj may be 1 to broadcast
- /// against arr.
- ///
- ///
- /// values to insert at those indices.
- /// Its shape and dimension are
- /// broadcast to match that of indices.
- ///
- ///
- /// The axis to take 1d slices along.
- /// If axis is None, the destination
- /// array is treated as if a flattened 1d view had been created of it.
- ///
- public void put_along_axis(NDarray indices, NDarray[] values, int axis)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- indices,
- values,
- axis,
- });
- var kwargs=new PyDict();
- dynamic py = __self__.InvokeMethod("put_along_axis", pyargs, kwargs);
- }
-
- ///
- /// Changes elements of an array based on conditional and input values.
- ///
- /// Sets a.flat[n] = values[n] for each n where mask.flat[n]==True.
- ///
- /// If values is not the same size as a and mask then it will repeat.
- ///
- /// This gives behavior different from a[mask] = values.
- ///
- ///
- /// Boolean mask array.
- /// It has to be the same shape as a.
- ///
- ///
- /// Values to put into a where mask is True.
- /// If values is smaller
- /// than a it will be repeated.
- ///
- public void putmask(NDarray mask, NDarray values)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- mask,
- values,
- });
- var kwargs=new PyDict();
- dynamic py = __self__.InvokeMethod("putmask", pyargs, kwargs);
- }
-
- ///
- /// Fill the main diagonal of the given array of any dimensionality.
- ///
- /// For an array a with a.ndim >= 2, the diagonal is the list of
- /// locations with indices a[i, ..., i] all identical.
- /// This function
- /// modifies the input array in-place, it does not return a value.
- ///
- /// Notes
- ///
- /// This functionality can be obtained via diag_indices, but internally
- /// this version uses a much faster implementation that never constructs the
- /// indices and uses simple slicing.
- ///
- ///
- /// Value to be written on the diagonal, its type must be compatible with
- /// that of the array a.
- ///
- ///
- /// For tall matrices in NumPy version up to 1.6.2, the
- /// diagonal “wrapped” after N columns.
- /// You can have this behavior
- /// with this option.
- /// This affects only tall matrices.
- ///
- public void fill_diagonal(ValueType val, bool wrap = false)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- val,
- });
- var kwargs=new PyDict();
- if (wrap!=false) kwargs["wrap"]=ToPython(wrap);
- dynamic py = __self__.InvokeMethod("fill_diagonal", pyargs, kwargs);
- }
-
- /*
- ///
- /// Efficient multi-dimensional iterator object to iterate over arrays.
- ///
- /// To get started using this object, see the
- /// introductory guide to array iteration.
- ///
- /// Notes
- ///
- /// nditer supersedes flatiter.
- /// The iterator implementation behind
- /// nditer is also exposed by the NumPy C API.
- ///
- /// The Python exposure supplies two iteration interfaces, one which follows
- /// the Python iterator protocol, and another which mirrors the C-style
- /// do-while pattern.
- /// The native Python approach is better in most cases, but
- /// if you need the iterator’s coordinates or index, use the C-style pattern.
- ///
- ///
- /// Flags to control the behavior of the iterator.
- ///
- ///
- /// This is a list of flags for each operand.
- /// At minimum, one of
- /// “readonly”, “readwrite”, or “writeonly” must be specified.
- ///
- ///
- /// The required data type(s) of the operands.
- /// If copying or buffering
- /// is enabled, the data will be converted to/from their original types.
- ///
- ///
- /// Controls the iteration order.
- /// ‘C’ means C order, ‘F’ means
- /// Fortran order, ‘A’ means ‘F’ order if all the arrays are Fortran
- /// contiguous, ‘C’ order otherwise, and ‘K’ means as close to the
- /// order the array elements appear in memory as possible.
- /// This also
- /// affects the element memory order of “allocate” operands, as they
- /// are allocated to be compatible with iteration order.
- ///
- /// Default is ‘K’.
- ///
- ///
- /// Controls what kind of data casting may occur when making a copy
- /// or buffering.
- /// Setting this to ‘unsafe’ is not recommended,
- /// as it can adversely affect accumulations.
- ///
- ///
- /// If provided, is a list of ints or None for each operands.
- ///
- /// The list of axes for an operand is a mapping from the dimensions
- /// of the iterator to the dimensions of the operand.
- /// A value of
- /// -1 can be placed for entries, causing that dimension to be
- /// treated as “newaxis”.
- ///
- ///
- /// The desired shape of the iterator.
- /// This allows “allocate” operands
- /// with a dimension mapped by op_axes not corresponding to a dimension
- /// of a different operand to get a value not equal to 1 for that
- /// dimension.
- ///
- ///
- /// When buffering is enabled, controls the size of the temporary
- /// buffers.
- /// Set to 0 for the default value.
- ///
- public void nditer(string[] flags = null, list of list of str op_flags = null, dtype or tuple of dtype(s) op_dtypes = null, string order = null, string casting = null, list of list of ints op_axes = null, tuple of ints itershape = null, int? buffersize = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (flags!=null) kwargs["flags"]=ToPython(flags);
- if (op_flags!=null) kwargs["op_flags"]=ToPython(op_flags);
- if (op_dtypes!=null) kwargs["op_dtypes"]=ToPython(op_dtypes);
- if (order!=null) kwargs["order"]=ToPython(order);
- if (casting!=null) kwargs["casting"]=ToPython(casting);
- if (op_axes!=null) kwargs["op_axes"]=ToPython(op_axes);
- if (itershape!=null) kwargs["itershape"]=ToPython(itershape);
- if (buffersize!=null) kwargs["buffersize"]=ToPython(buffersize);
- dynamic py = __self__.InvokeMethod("nditer", pyargs, kwargs);
- }
- */
-
- ///
- /// Multidimensional index iterator.
- ///
- /// Return an iterator yielding pairs of array coordinates and values.
- ///
- public void ndenumerate()
- {
- //auto-generated code, do not change
- var __self__=self;
- dynamic py = __self__.InvokeMethod("ndenumerate");
- }
-
- /*
- ///
- /// Create nditers for use in nested loops
- ///
- /// Create a tuple of nditer objects which iterate in nested loops over
- /// different axes of the op argument.
- /// The first iterator is used in the
- /// outermost loop, the last in the innermost loop.
- /// Advancing one will change
- /// the subsequent iterators to point at its new element.
- ///
- ///
- /// Each item is used as an “op_axes” argument to an nditer
- ///
- ///
- /// An nditer for each item in axes, outermost first
- ///
- public tuple of nditer nested_iters(params int[] axes)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axes!=null) kwargs["axes"]=ToPython(axes);
- dynamic py = __self__.InvokeMethod("nested_iters", pyargs, kwargs);
- return ToCsharp(py);
- }
- */
-
- /*
- ///
- /// Return a string representation of an array.
- ///
- /// Notes
- ///
- /// If a formatter is specified for a certain type, the precision keyword is
- /// ignored for that type.
- ///
- /// This is a very flexible function; array_repr and array_str are using
- /// array2string internally so keywords with the same name should work
- /// identically in all three functions.
- ///
- ///
- /// The maximum number of columns the string should span.
- /// Newline
- /// characters splits the string appropriately after array elements.
- ///
- ///
- /// Floating point precision.
- /// Default is the current printing
- /// precision (usually 8), which can be altered using set_printoptions.
- ///
- ///
- /// Represent very small numbers as zero.
- /// A number is “very small” if it
- /// is smaller than the current printing precision.
- ///
- ///
- /// Inserted between elements.
- ///
- ///
- /// The length of the prefix and suffix strings are used to respectively
- /// align and wrap the output.
- /// An array is typically printed as:
- ///
- /// The output is left-padded by the length of the prefix string, and
- /// wrapping is forced at the column max_line_width - len(suffix).
- ///
- /// It should be noted that the content of prefix and suffix strings are
- /// not included in the output.
- ///
- ///
- /// If not None, the keys should indicate the type(s) that the respective
- /// formatting function applies to.
- /// Callables should return a string.
- ///
- /// Types that are not specified (by their corresponding keys) are handled
- /// by the default formatters.
- /// Individual types for which a formatter
- /// can be set are:
- ///
- /// Other keys that can be used to set a group of types at once are:
- ///
- ///
- /// Total number of array elements which trigger summarization
- /// rather than full repr.
- ///
- ///
- /// Number of array items in summary at beginning and end of
- /// each dimension.
- ///
- ///
- /// Controls printing of the sign of floating-point types.
- /// If ‘+’, always
- /// print the sign of positive values.
- /// If ‘ ‘, always prints a space
- /// (whitespace character) in the sign position of positive values.
- /// If
- /// ‘-‘, omit the sign character of positive values.
- ///
- ///
- /// Controls the interpretation of the precision option for
- /// floating-point types.
- /// Can take the following values:
- ///
- ///
- /// If set to the string ‘1.13’ enables 1.13 legacy printing mode.
- /// This
- /// approximates numpy 1.13 print output by including a space in the sign
- /// position of floats and different behavior for 0d arrays.
- /// If set to
- /// False, disables legacy mode.
- /// Unrecognized strings will be ignored
- /// with a warning for forward compatibility.
- ///
- ///
- /// String representation of the array.
- ///
- public string array2string(int? max_line_width = null, int? precision = null, bool? suppress_small = null, string separator = " ", string prefix = "", string suffix = "", dict of callables formatter = null, int? threshold = null, int? edgeitems = null, string sign = null, string floatmode = null, string or False legacy = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (max_line_width!=null) kwargs["max_line_width"]=ToPython(max_line_width);
- if (precision!=null) kwargs["precision"]=ToPython(precision);
- if (suppress_small!=null) kwargs["suppress_small"]=ToPython(suppress_small);
- if (separator!=" ") kwargs["separator"]=ToPython(separator);
- if (prefix!="") kwargs["prefix"]=ToPython(prefix);
- if (suffix!="") kwargs["suffix"]=ToPython(suffix);
- if (formatter!=null) kwargs["formatter"]=ToPython(formatter);
- if (threshold!=null) kwargs["threshold"]=ToPython(threshold);
- if (edgeitems!=null) kwargs["edgeitems"]=ToPython(edgeitems);
- if (sign!=null) kwargs["sign"]=ToPython(sign);
- if (floatmode!=null) kwargs["floatmode"]=ToPython(floatmode);
- if (legacy!=null) kwargs["legacy"]=ToPython(legacy);
- dynamic py = __self__.InvokeMethod("array2string", pyargs, kwargs);
- return ToCsharp(py);
- }
- */
-
- ///
- /// Return the string representation of an array.
- ///
- ///
- /// The maximum number of columns the string should span.
- /// Newline
- /// characters split the string appropriately after array elements.
- ///
- ///
- /// Floating point precision.
- /// Default is the current printing precision
- /// (usually 8), which can be altered using set_printoptions.
- ///
- ///
- /// Represent very small numbers as zero, default is False.
- /// Very small
- /// is defined by precision, if the precision is 8 then
- /// numbers smaller than 5e-9 are represented as zero.
- ///
- ///
- /// The string representation of an array.
- ///
- public string array_repr(int? max_line_width = null, int? precision = null, bool? suppress_small = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (max_line_width!=null) kwargs["max_line_width"]=ToPython(max_line_width);
- if (precision!=null) kwargs["precision"]=ToPython(precision);
- if (suppress_small!=null) kwargs["suppress_small"]=ToPython(suppress_small);
- dynamic py = __self__.InvokeMethod("array_repr", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return a string representation of the data in an array.
- ///
- /// The data in the array is returned as a single string.
- /// This function is
- /// similar to array_repr, the difference being that array_repr also
- /// returns information on the kind of array and its data type.
- ///
- ///
- /// Inserts newlines if text is longer than max_line_width.
- /// The
- /// default is, indirectly, 75.
- ///
- ///
- /// Floating point precision.
- /// Default is the current printing precision
- /// (usually 8), which can be altered using set_printoptions.
- ///
- ///
- /// Represent numbers “very close” to zero as zero; default is False.
- ///
- /// Very close is defined by precision: if the precision is 8, e.g.,
- /// numbers smaller (in absolute value) than 5e-9 are represented as
- /// zero.
- ///
- public void array_str(int? max_line_width = null, int? precision = null, bool? suppress_small = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (max_line_width!=null) kwargs["max_line_width"]=ToPython(max_line_width);
- if (precision!=null) kwargs["precision"]=ToPython(precision);
- if (suppress_small!=null) kwargs["suppress_small"]=ToPython(suppress_small);
- dynamic py = __self__.InvokeMethod("array_str", pyargs, kwargs);
- }
-
- ///
- /// Dot product of two arrays.
- /// Specifically,
- ///
- ///
- /// Second argument.
- ///
- ///
- /// Output argument.
- /// This must have the exact kind that would be returned
- /// if it was not used.
- /// In particular, it must have the right type, must be
- /// C-contiguous, and its dtype must be the dtype that would be returned
- /// for dot(a,b).
- /// This is a performance feature.
- /// Therefore, if these
- /// conditions are not met, an exception is raised, instead of attempting
- /// to be flexible.
- ///
- ///
- /// Returns the dot product of a and b.
- /// If a and b are both
- /// scalars or both 1-D arrays then a scalar is returned; otherwise
- /// an array is returned.
- ///
- /// If out is given, then it is returned.
- ///
- public NDarray dot(NDarray b, NDarray @out = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- b,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- dynamic py = __self__.InvokeMethod("dot", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the dot product of two vectors.
- ///
- /// The vdot(a, b) function handles complex numbers differently than
- /// dot(a, b).
- /// If the first argument is complex the complex conjugate
- /// of the first argument is used for the calculation of the dot product.
- ///
- /// Note that vdot handles multidimensional arrays differently than dot:
- /// it does not perform a matrix product, but flattens input arguments
- /// to 1-D vectors first.
- /// Consequently, it should only be used for vectors.
- ///
- ///
- /// Second argument to the dot product.
- ///
- ///
- /// Dot product of a and b.
- /// Can be an int, float, or
- /// complex depending on the types of a and b.
- ///
- public NDarray vdot(NDarray b)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- b,
- });
- var kwargs=new PyDict();
- dynamic py = __self__.InvokeMethod("vdot", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Inner product of two arrays.
- ///
- /// Ordinary inner product of vectors for 1-D arrays (without complex
- /// conjugation), in higher dimensions a sum product over the last axes.
- ///
- /// Notes
- ///
- /// For vectors (1-D arrays) it computes the ordinary inner-product:
- ///
- /// More generally, if ndim(a) = r > 0 and ndim(b) = s > 0:
- ///
- /// or explicitly:
- ///
- /// In addition a or b may be scalars, in which case:
- ///
- ///
- /// If a and b are nonscalar, their last dimensions must match.
- ///
- ///
- /// out.shape = a.shape[:-1] + b.shape[:-1]
- ///
- public NDarray inner(NDarray a)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- a,
- });
- var kwargs=new PyDict();
- dynamic py = __self__.InvokeMethod("inner", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Compute the outer product of two vectors.
- ///
- /// Given two vectors, a = [a0, a1, ..., aM] and
- /// b = [b0, b1, ..., bN],
- /// the outer product [1] is:
- ///
- /// References
- ///
- ///
- /// Second input vector.
- /// Input is flattened if
- /// not already 1-dimensional.
- ///
- ///
- /// A location where the result is stored
- ///
- ///
- /// out[i, j] = a[i] * b[j]
- ///
- public NDarray outer(NDarray b, NDarray @out = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- b,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- dynamic py = __self__.InvokeMethod("outer", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Matrix product of two arrays.
- ///
- /// Notes
- ///
- /// The behavior depends on the arguments in the following way.
- ///
- /// matmul differs from dot in two important ways:
- ///
- /// The matmul function implements the semantics of the @ operator introduced
- /// in Python 3.5 following PEP465.
- ///
- ///
- /// Input arrays, scalars not allowed.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that matches the signature (n,k),(k,m)->(n,m).
- /// If not
- /// provided or None, a freshly-allocated array is returned.
- ///
- ///
- /// The matrix product of the inputs.
- ///
- /// This is a scalar only when both x1, x2 are 1-d vectors.
- ///
- public NDarray matmul(NDarray x1, NDarray @out = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x1,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- dynamic py = __self__.InvokeMethod("matmul", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Compute tensor dot product along specified axes for arrays >= 1-D.
- ///
- /// Given two tensors (arrays of dimension greater than or equal to one),
- /// a and b, and an array_like object containing two array_like
- /// objects, (a_axes, b_axes), sum the products of a’s and b’s
- /// elements (components) over the axes specified by a_axes and
- /// b_axes.
- /// The third argument can be a single non-negative
- /// integer_like scalar, N; if it is such, then the last N
- /// dimensions of a and the first N dimensions of b are summed
- /// over.
- ///
- /// Notes
- ///
- /// When axes is integer_like, the sequence for evaluation will be: first
- /// the -Nth axis in a and 0th axis in b, and the -1th axis in a and
- /// Nth axis in b last.
- ///
- /// When there is more than one axis to sum over - and they are not the last
- /// (first) axes of a (b) - the argument axes should consist of
- /// two sequences of the same length, with the first axis to sum over given
- /// first in both sequences, the second axis second, and so forth.
- ///
- ///
- /// Tensors to “dot”.
- ///
- public NDarray tensordot(NDarray a, int[] axes = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- a,
- });
- var kwargs=new PyDict();
- if (axes!=null) kwargs["axes"]=ToPython(axes);
- dynamic py = __self__.InvokeMethod("tensordot", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Kronecker product of two arrays.
- ///
- /// Computes the Kronecker product, a composite array made of blocks of the
- /// second array scaled by the first.
- ///
- /// Notes
- ///
- /// The function assumes that the number of dimensions of a and b
- /// are the same, if necessary prepending the smallest with ones.
- ///
- /// If a.shape = (r0,r1,..,rN) and b.shape = (s0,s1,…,sN),
- /// the Kronecker product has shape (r0*s0, r1*s1, …, rN*SN).
- ///
- /// The elements are products of elements from a and b, organized
- /// explicitly by:
- ///
- /// where:
- ///
- /// In the common 2-D case (N=1), the block structure can be visualized:
- ///
- public NDarray kron(NDarray a)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- a,
- });
- var kwargs=new PyDict();
- dynamic py = __self__.InvokeMethod("kron", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the sum along diagonals of the array.
- ///
- /// If a is 2-D, the sum along its diagonal with the given offset
- /// is returned, i.e., the sum of elements a[i,i+offset] for all i.
- ///
- /// If a has more than two dimensions, then the axes specified by axis1 and
- /// axis2 are used to determine the 2-D sub-arrays whose traces are returned.
- ///
- /// The shape of the resulting array is the same as that of a with axis1
- /// and axis2 removed.
- ///
- ///
- /// Offset of the diagonal from the main diagonal.
- /// Can be both positive
- /// and negative.
- /// Defaults to 0.
- ///
- ///
- /// Axes to be used as the first and second axis of the 2-D sub-arrays
- /// from which the diagonals should be taken.
- /// Defaults are the first two
- /// axes of a.
- ///
- ///
- /// Axes to be used as the first and second axis of the 2-D sub-arrays
- /// from which the diagonals should be taken.
- /// Defaults are the first two
- /// axes of a.
- ///
- ///
- /// Determines the data-type of the returned array and of the accumulator
- /// where the elements are summed.
- /// If dtype has the value None and a is
- /// of integer type of precision less than the default integer
- /// precision, then the default integer precision is used.
- /// Otherwise,
- /// the precision is the same as that of a.
- ///
- ///
- /// Array into which the output is placed.
- /// Its type is preserved and
- /// it must be of the right shape to hold the output.
- ///
- ///
- /// If a is 2-D, the sum along the diagonal is returned.
- /// If a has
- /// larger dimensions, then an array of sums along diagonals is returned.
- ///
- public NDarray trace(int? offset = 0, int? axis2 = null, int? axis1 = null, Dtype dtype = null, NDarray @out = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (offset!=0) kwargs["offset"]=ToPython(offset);
- if (axis2!=null) kwargs["axis2"]=ToPython(axis2);
- if (axis1!=null) kwargs["axis1"]=ToPython(axis1);
- if (dtype!=null) kwargs["dtype"]=ToPython(dtype);
- if (@out!=null) kwargs["out"]=ToPython(@out);
- dynamic py = __self__.InvokeMethod("trace", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Test whether all array elements along a given axis evaluate to True.
- ///
- /// Notes
- ///
- /// Not a Number (NaN), positive infinity and negative infinity
- /// evaluate to True because these are not equal to zero.
- ///
- ///
- /// Axis or axes along which a logical AND reduction is performed.
- ///
- /// The default (axis = None) is to perform a logical AND over all
- /// the dimensions of the input array.
- /// axis may be negative, in
- /// which case it counts from the last to the first axis.
- ///
- /// If this is a tuple of ints, a reduction is performed on multiple
- /// axes, instead of a single axis or all the axes as before.
- ///
- ///
- /// Alternate output array in which to place the result.
- ///
- /// It must have the same shape as the expected output and its
- /// type is preserved (e.g., if dtype(out) is float, the result
- /// will consist of 0.0’s and 1.0’s).
- /// See doc.ufuncs (Section
- /// “Output arguments”) for more details.
- ///
- ///
- /// If this is set to True, the axes which are reduced are left
- /// in the result as dimensions with size one.
- /// With this option,
- /// the result will broadcast correctly against the input array.
- ///
- /// If the default value is passed, then keepdims will not be
- /// passed through to the all method of sub-classes of
- /// ndarray, however any non-default value will be.
- /// If the
- /// sub-class’ method does not implement keepdims any
- /// exceptions will be raised.
- ///
- ///
- /// A new boolean or array is returned unless out is specified,
- /// in which case a reference to out is returned.
- ///
- public NDarray all(Axis axis, NDarray @out = null, bool? keepdims = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (keepdims!=null) kwargs["keepdims"]=ToPython(keepdims);
- dynamic py = __self__.InvokeMethod("all", pyargs, kwargs);
- return ToCsharp>(py);
- }
-
- ///
- /// Test whether all array elements along a given axis evaluate to True.
- ///
- /// Notes
- ///
- /// Not a Number (NaN), positive infinity and negative infinity
- /// evaluate to True because these are not equal to zero.
- ///
- ///
- /// A new boolean or array is returned unless out is specified,
- /// in which case a reference to out is returned.
- ///
- public bool all()
- {
- //auto-generated code, do not change
- var __self__=self;
- dynamic py = __self__.InvokeMethod("all");
- return ToCsharp(py);
- }
-
- ///
- /// Test whether any array element along a given axis evaluates to True.
- ///
- /// Returns single boolean unless axis is not None
- ///
- /// Notes
- ///
- /// Not a Number (NaN), positive infinity and negative infinity evaluate
- /// to True because these are not equal to zero.
- ///
- ///
- /// Axis or axes along which a logical OR reduction is performed.
- ///
- /// The default (axis = None) is to perform a logical OR over all
- /// the dimensions of the input array.
- /// axis may be negative, in
- /// which case it counts from the last to the first axis.
- ///
- /// If this is a tuple of ints, a reduction is performed on multiple
- /// axes, instead of a single axis or all the axes as before.
- ///
- ///
- /// Alternate output array in which to place the result.
- /// It must have
- /// the same shape as the expected output and its type is preserved
- /// (e.g., if it is of type float, then it will remain so, returning
- /// 1.0 for True and 0.0 for False, regardless of the type of a).
- ///
- /// See doc.ufuncs (Section “Output arguments”) for details.
- ///
- ///
- /// If this is set to True, the axes which are reduced are left
- /// in the result as dimensions with size one.
- /// With this option,
- /// the result will broadcast correctly against the input array.
- ///
- /// If the default value is passed, then keepdims will not be
- /// passed through to the any method of sub-classes of
- /// ndarray, however any non-default value will be.
- /// If the
- /// sub-class’ method does not implement keepdims any
- /// exceptions will be raised.
- ///
- ///
- /// A new boolean or ndarray is returned unless out is specified,
- /// in which case a reference to out is returned.
- ///
- public NDarray any(Axis axis, NDarray @out = null, bool? keepdims = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (keepdims!=null) kwargs["keepdims"]=ToPython(keepdims);
- dynamic py = __self__.InvokeMethod("any", pyargs, kwargs);
- return ToCsharp>(py);
- }
-
- ///
- /// Test whether any array element along a given axis evaluates to True.
- ///
- /// Returns single boolean unless axis is not None
- ///
- /// Notes
- ///
- /// Not a Number (NaN), positive infinity and negative infinity evaluate
- /// to True because these are not equal to zero.
- ///
- ///
- /// A new boolean or ndarray is returned unless out is specified,
- /// in which case a reference to out is returned.
- ///
- public bool any()
- {
- //auto-generated code, do not change
- var __self__=self;
- dynamic py = __self__.InvokeMethod("any");
- return ToCsharp(py);
- }
-
- ///
- /// Test element-wise for finiteness (not infinity or not Not a Number).
- ///
- /// The result is returned as a boolean array.
- ///
- /// Notes
- ///
- /// Not a Number, positive infinity and negative infinity are considered
- /// to be non-finite.
- ///
- /// NumPy uses the IEEE Standard for Binary Floating-Point for Arithmetic
- /// (IEEE 754).
- /// This means that Not a Number is not equivalent to infinity.
- ///
- /// Also that positive infinity is not equivalent to negative infinity.
- /// But
- /// infinity is equivalent to positive infinity.
- /// Errors result if the
- /// second argument is also supplied when x is a scalar input, or if
- /// first and second arguments have different shapes.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// True where x is not positive infinity, negative infinity,
- /// or NaN; false otherwise.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray isfinite(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("isfinite", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Test element-wise for positive or negative infinity.
- ///
- /// Returns a boolean array of the same shape as x, True where x ==
- /// +/-inf, otherwise False.
- ///
- /// Notes
- ///
- /// NumPy uses the IEEE Standard for Binary Floating-Point for Arithmetic
- /// (IEEE 754).
- ///
- /// Errors result if the second argument is supplied when the first
- /// argument is a scalar, or if the first and second arguments have
- /// different shapes.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// True where x is positive or negative infinity, false otherwise.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray isinf(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("isinf", pyargs, kwargs);
- return ToCsharp>(py);
- }
-
- ///
- /// Test element-wise for NaN and return result as a boolean array.
- ///
- /// Notes
- ///
- /// NumPy uses the IEEE Standard for Binary Floating-Point for Arithmetic
- /// (IEEE 754).
- /// This means that Not a Number is not equivalent to infinity.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// True where x is NaN, false otherwise.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray isnan(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("isnan", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Test element-wise for NaT (not a time) and return result as a boolean array.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// True where x is NaT, false otherwise.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray isnat(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("isnat", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Test element-wise for negative infinity, return result as bool array.
- ///
- /// Notes
- ///
- /// NumPy uses the IEEE Standard for Binary Floating-Point for Arithmetic
- /// (IEEE 754).
- ///
- /// Errors result if the second argument is also supplied when x is a scalar
- /// input, if first and second arguments have different shapes, or if the
- /// first argument has complex values.
- ///
- ///
- /// A boolean array with the same shape and type as x to store the
- /// result.
- ///
- ///
- /// A boolean array with the same dimensions as the input.
- ///
- /// If second argument is not supplied then a numpy boolean array is
- /// returned with values True where the corresponding element of the
- /// input is negative infinity and values False where the element of
- /// the input is not negative infinity.
- ///
- /// If a second argument is supplied the result is stored there.
- /// If the
- /// type of that array is a numeric type the result is represented as
- /// zeros and ones, if the type is boolean then as False and True.
- /// The
- /// return value out is then a reference to that array.
- ///
- public NDarray isneginf(NDarray @out = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- dynamic py = __self__.InvokeMethod("isneginf", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Test element-wise for positive infinity, return result as bool array.
- ///
- /// Notes
- ///
- /// NumPy uses the IEEE Standard for Binary Floating-Point for Arithmetic
- /// (IEEE 754).
- ///
- /// Errors result if the second argument is also supplied when x is a scalar
- /// input, if first and second arguments have different shapes, or if the
- /// first argument has complex values
- ///
- ///
- /// A boolean array with the same shape as x to store the result.
- ///
- ///
- /// A boolean array with the same dimensions as the input.
- ///
- /// If second argument is not supplied then a boolean array is returned
- /// with values True where the corresponding element of the input is
- /// positive infinity and values False where the element of the input is
- /// not positive infinity.
- ///
- /// If a second argument is supplied the result is stored there.
- /// If the
- /// type of that array is a numeric type the result is represented as zeros
- /// and ones, if the type is boolean then as False and True.
- ///
- /// The return value out is then a reference to that array.
- ///
- public NDarray isposinf(NDarray y = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (y!=null) kwargs["y"]=ToPython(y);
- dynamic py = __self__.InvokeMethod("isposinf", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Returns a bool array, where True if input element is complex.
- ///
- /// What is tested is whether the input has a non-zero imaginary part, not if
- /// the input type is complex.
- ///
- ///
- /// Output array.
- ///
- public NDarray iscomplex()
- {
- //auto-generated code, do not change
- var __self__=self;
- dynamic py = __self__.InvokeMethod("iscomplex");
- return ToCsharp(py);
- }
-
- ///
- /// Returns True if the array is Fortran contiguous but not C contiguous.
- ///
- /// This function is obsolete and, because of changes due to relaxed stride
- /// checking, its return value for the same array may differ for versions
- /// of NumPy >= 1.10.0 and previous versions.
- /// If you only want to check if an
- /// array is Fortran contiguous use a.flags.f_contiguous instead.
- ///
- public bool isfortran()
- {
- //auto-generated code, do not change
- var __self__=self;
- dynamic py = __self__.InvokeMethod("isfortran");
- return ToCsharp(py);
- }
-
- ///
- /// Returns a bool array, where True if input element is real.
- ///
- /// If element has complex type with zero complex part, the return value
- /// for that element is True.
- ///
- ///
- /// Boolean array of same shape as x.
- ///
- public NDarray isreal()
- {
- //auto-generated code, do not change
- var __self__=self;
- dynamic py = __self__.InvokeMethod("isreal");
- return ToCsharp(py);
- }
-
- ///
- /// Compute the truth value of x1 AND x2 element-wise.
- ///
- ///
- /// Input arrays.
- /// x1 and x2 must be of the same shape.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Boolean result with the same shape as x1 and x2 of the logical
- /// AND operation on corresponding elements of x1 and x2.
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray logical_and(NDarray x1, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x1,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("logical_and", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Compute the truth value of x1 OR x2 element-wise.
- ///
- ///
- /// Logical OR is applied to the elements of x1 and x2.
- /// They have to be of the same shape.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Boolean result with the same shape as x1 and x2 of the logical
- /// OR operation on elements of x1 and x2.
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray logical_or(NDarray x1, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x1,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("logical_or", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Compute the truth value of NOT x element-wise.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Boolean result with the same shape as x of the NOT operation
- /// on elements of x.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray logical_not(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("logical_not", pyargs, kwargs);
- return ToCsharp>(py);
- }
-
- ///
- /// Compute the truth value of x1 XOR x2, element-wise.
- ///
- ///
- /// Logical XOR is applied to the elements of x1 and x2. They must
- /// be broadcastable to the same shape.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Boolean result of the logical XOR operation applied to the elements
- /// of x1 and x2; the shape is determined by whether or not
- /// broadcasting of one or both arrays was required.
- ///
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray logical_xor(NDarray x1, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x1,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("logical_xor", pyargs, kwargs);
- return ToCsharp>(py);
- }
-
- ///
- /// Returns True if two arrays are element-wise equal within a tolerance.
- ///
- /// The tolerance values are positive, typically very small numbers.
- /// The
- /// relative difference (rtol * abs(b)) and the absolute difference
- /// atol are added together to compare against the absolute difference
- /// between a and b.
- ///
- /// If either array contains one or more NaNs, False is returned.
- ///
- /// Infs are treated as equal if they are in the same place and of the same
- /// sign in both arrays.
- ///
- /// Notes
- ///
- /// If the following equation is element-wise True, then allclose returns
- /// True.
- ///
- /// The above equation is not symmetric in a and b, so that
- /// allclose(a, b) might be different from allclose(b, a) in
- /// some rare cases.
- ///
- /// The comparison of a and b uses standard broadcasting, which
- /// means that a and b need not have the same shape in order for
- /// allclose(a, b) to evaluate to True.
- /// The same is true for
- /// equal but not array_equal.
- ///
- ///
- /// Input arrays to compare.
- ///
- ///
- /// The relative tolerance parameter (see Notes).
- ///
- ///
- /// The absolute tolerance parameter (see Notes).
- ///
- ///
- /// Whether to compare NaN’s as equal.
- /// If True, NaN’s in a will be
- /// considered equal to NaN’s in b in the output array.
- ///
- ///
- /// Returns True if the two arrays are equal within the given
- /// tolerance; False otherwise.
- ///
- public bool allclose(NDarray a, float rtol = 1e-05f, float atol = 1e-08f, bool equal_nan = false)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- a,
- });
- var kwargs=new PyDict();
- if (rtol!=1e-05f) kwargs["rtol"]=ToPython(rtol);
- if (atol!=1e-08f) kwargs["atol"]=ToPython(atol);
- if (equal_nan!=false) kwargs["equal_nan"]=ToPython(equal_nan);
- dynamic py = __self__.InvokeMethod("allclose", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Returns a boolean array where two arrays are element-wise equal within a
- /// tolerance.
- ///
- /// The tolerance values are positive, typically very small numbers.
- /// The
- /// relative difference (rtol * abs(b)) and the absolute difference
- /// atol are added together to compare against the absolute difference
- /// between a and b.
- ///
- /// Notes
- ///
- /// For finite values, isclose uses the following equation to test whether
- /// two floating point values are equivalent.
- ///
- /// Unlike the built-in math.isclose, the above equation is not symmetric
- /// in a and b – it assumes b is the reference value – so that
- /// isclose(a, b) might be different from isclose(b, a).
- /// Furthermore,
- /// the default value of atol is not zero, and is used to determine what
- /// small values should be considered close to zero.
- /// The default value is
- /// appropriate for expected values of order unity: if the expected values
- /// are significantly smaller than one, it can result in false positives.
- ///
- /// atol should be carefully selected for the use case at hand.
- /// A zero value
- /// for atol will result in False if either a or b is zero.
- ///
- ///
- /// Input arrays to compare.
- ///
- ///
- /// The relative tolerance parameter (see Notes).
- ///
- ///
- /// The absolute tolerance parameter (see Notes).
- ///
- ///
- /// Whether to compare NaN’s as equal.
- /// If True, NaN’s in a will be
- /// considered equal to NaN’s in b in the output array.
- ///
- ///
- /// Returns a boolean array of where a and b are equal within the
- /// given tolerance.
- /// If both a and b are scalars, returns a single
- /// boolean value.
- ///
- public NDarray isclose(NDarray a, float rtol = 1e-05f, float atol = 1e-08f, bool equal_nan = false)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- a,
- });
- var kwargs=new PyDict();
- if (rtol!=1e-05f) kwargs["rtol"]=ToPython(rtol);
- if (atol!=1e-08f) kwargs["atol"]=ToPython(atol);
- if (equal_nan!=false) kwargs["equal_nan"]=ToPython(equal_nan);
- dynamic py = __self__.InvokeMethod("isclose", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// True if two arrays have the same shape and elements, False otherwise.
- ///
- ///
- /// Input arrays.
- ///
- ///
- /// Returns True if the arrays are equal.
- ///
- public bool array_equal(NDarray a1)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- a1,
- });
- var kwargs=new PyDict();
- dynamic py = __self__.InvokeMethod("array_equal", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Returns True if input arrays are shape consistent and all elements equal.
- ///
- /// Shape consistent means they are either the same shape, or one input array
- /// can be broadcasted to create the same shape as the other one.
- ///
- ///
- /// Input arrays.
- ///
- ///
- /// True if equivalent, False otherwise.
- ///
- public bool array_equiv(NDarray a1)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- a1,
- });
- var kwargs=new PyDict();
- dynamic py = __self__.InvokeMethod("array_equiv", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the truth value of (x1 > x2) element-wise.
- ///
- ///
- /// Input arrays.
- /// If x1.shape != x2.shape, they must be
- /// broadcastable to a common shape (which may be the shape of one or
- /// the other).
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Output array, element-wise comparison of x1 and x2.
- /// Typically of type bool, unless dtype=object is passed.
- ///
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray greater(NDarray x1, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x1,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("greater", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the truth value of (x1 >= x2) element-wise.
- ///
- ///
- /// Input arrays.
- /// If x1.shape != x2.shape, they must be
- /// broadcastable to a common shape (which may be the shape of one or
- /// the other).
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Output array, element-wise comparison of x1 and x2.
- /// Typically of type bool, unless dtype=object is passed.
- ///
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray greater_equal(NDarray x1, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x1,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("greater_equal", pyargs, kwargs);
- return ToCsharp>(py);
- }
-
- ///
- /// Return the truth value of (x1 < x2) element-wise.
- ///
- ///
- /// Input arrays.
- /// If x1.shape != x2.shape, they must be
- /// broadcastable to a common shape (which may be the shape of one or
- /// the other).
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Output array, element-wise comparison of x1 and x2.
- /// Typically of type bool, unless dtype=object is passed.
- ///
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray less(NDarray x1, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x1,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("less", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the truth value of (x1 =< x2) element-wise.
- ///
- ///
- /// Input arrays.
- /// If x1.shape != x2.shape, they must be
- /// broadcastable to a common shape (which may be the shape of one or
- /// the other).
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Output array, element-wise comparison of x1 and x2.
- /// Typically of type bool, unless dtype=object is passed.
- ///
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray less_equal(NDarray x1, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x1,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("less_equal", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return (x1 == x2) element-wise.
- ///
- ///
- /// Input arrays of the same shape.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Output array, element-wise comparison of x1 and x2.
- /// Typically of type bool, unless dtype=object is passed.
- ///
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray equal(NDarray x1, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x1,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("equal", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return (x1 != x2) element-wise.
- ///
- ///
- /// Input arrays.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Output array, element-wise comparison of x1 and x2.
- /// Typically of type bool, unless dtype=object is passed.
- ///
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray not_equal(NDarray x1, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x1,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("not_equal", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Trigonometric sine, element-wise.
- ///
- /// Notes
- ///
- /// The sine is one of the fundamental functions of trigonometry (the
- /// mathematical study of triangles).
- /// Consider a circle of radius 1
- /// centered on the origin.
- /// A ray comes in from the axis, makes
- /// an angle at the origin (measured counter-clockwise from that axis), and
- /// departs from the origin.
- /// The coordinate of the outgoing
- /// ray’s intersection with the unit circle is the sine of that angle.
- /// It
- /// ranges from -1 for to +1 for The
- /// function has zeroes where the angle is a multiple of .
- /// Sines of angles between and are negative.
- ///
- /// The numerous properties of the sine and related functions are included
- /// in any standard trigonometry text.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The sine of each element of x.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray sin(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("sin", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Cosine element-wise.
- ///
- /// Notes
- ///
- /// If out is provided, the function writes the result into it,
- /// and returns a reference to out.
- /// (See Examples)
- ///
- /// References
- ///
- /// M.
- /// Abramowitz and I.
- /// A.
- /// Stegun, Handbook of Mathematical Functions.
- ///
- /// New York, NY: Dover, 1972.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The corresponding cosine values.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray cos(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("cos", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Compute tangent element-wise.
- ///
- /// Equivalent to np.sin(x)/np.cos(x) element-wise.
- ///
- /// Notes
- ///
- /// If out is provided, the function writes the result into it,
- /// and returns a reference to out.
- /// (See Examples)
- ///
- /// References
- ///
- /// M.
- /// Abramowitz and I.
- /// A.
- /// Stegun, Handbook of Mathematical Functions.
- ///
- /// New York, NY: Dover, 1972.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The corresponding tangent values.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray tan(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("tan", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Inverse sine, element-wise.
- ///
- /// Notes
- ///
- /// arcsin is a multivalued function: for each x there are infinitely
- /// many numbers z such that . The convention is to
- /// return the angle z whose real part lies in [-pi/2, pi/2].
- ///
- /// For real-valued input data types, arcsin always returns real output.
- ///
- /// For each value that cannot be expressed as a real number or infinity,
- /// it yields nan and sets the invalid floating point error flag.
- ///
- /// For complex-valued input, arcsin is a complex analytic function that
- /// has, by convention, the branch cuts [-inf, -1] and [1, inf] and is
- /// continuous from above on the former and from below on the latter.
- ///
- /// The inverse sine is also known as asin or sin^{-1}.
- ///
- /// References
- ///
- /// Abramowitz, M.
- /// and Stegun, I.
- /// A., Handbook of Mathematical Functions,
- /// 10th printing, New York: Dover, 1964, pp.
- /// 79ff.
- ///
- /// http://www.math.sfu.ca/~cbm/aands/
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The inverse sine of each element in x, in radians and in the
- /// closed interval [-pi/2, pi/2].
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray arcsin(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("arcsin", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Trigonometric inverse cosine, element-wise.
- ///
- /// The inverse of cos so that, if y = cos(x), then x = arccos(y).
- ///
- /// Notes
- ///
- /// arccos is a multivalued function: for each x there are infinitely
- /// many numbers z such that cos(z) = x.
- /// The convention is to return
- /// the angle z whose real part lies in [0, pi].
- ///
- /// For real-valued input data types, arccos always returns real output.
- ///
- /// For each value that cannot be expressed as a real number or infinity,
- /// it yields nan and sets the invalid floating point error flag.
- ///
- /// For complex-valued input, arccos is a complex analytic function that
- /// has branch cuts [-inf, -1] and [1, inf] and is continuous from
- /// above on the former and from below on the latter.
- ///
- /// The inverse cos is also known as acos or cos^-1.
- ///
- /// References
- ///
- /// M.
- /// Abramowitz and I.A.
- /// Stegun, “Handbook of Mathematical Functions”,
- /// 10th printing, 1964, pp.
- /// 79. http://www.math.sfu.ca/~cbm/aands/
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The angle of the ray intersecting the unit circle at the given
- /// x-coordinate in radians [0, pi].
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray arccos(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("arccos", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Trigonometric inverse tangent, element-wise.
- ///
- /// The inverse of tan, so that if y = tan(x) then x = arctan(y).
- ///
- /// Notes
- ///
- /// arctan is a multi-valued function: for each x there are infinitely
- /// many numbers z such that tan(z) = x.
- /// The convention is to return
- /// the angle z whose real part lies in [-pi/2, pi/2].
- ///
- /// For real-valued input data types, arctan always returns real output.
- ///
- /// For each value that cannot be expressed as a real number or infinity,
- /// it yields nan and sets the invalid floating point error flag.
- ///
- /// For complex-valued input, arctan is a complex analytic function that
- /// has [1j, infj] and [-1j, -infj] as branch cuts, and is continuous
- /// from the left on the former and from the right on the latter.
- ///
- /// The inverse tangent is also known as atan or tan^{-1}.
- ///
- /// References
- ///
- /// Abramowitz, M.
- /// and Stegun, I.
- /// A., Handbook of Mathematical Functions,
- /// 10th printing, New York: Dover, 1964, pp.
- /// 79.
- /// http://www.math.sfu.ca/~cbm/aands/
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Out has the same shape as x.
- /// Its real part is in
- /// [-pi/2, pi/2] (arctan(+/-inf) returns +/-pi/2).
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray arctan(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("arctan", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Given the “legs” of a right triangle, return its hypotenuse.
- ///
- /// Equivalent to sqrt(x1**2 + x2**2), element-wise.
- /// If x1 or
- /// x2 is scalar_like (i.e., unambiguously cast-able to a scalar type),
- /// it is broadcast for use with each element of the other argument.
- ///
- /// (See Examples)
- ///
- ///
- /// Leg of the triangle(s).
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The hypotenuse of the triangle(s).
- ///
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray hypot(NDarray x1, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x1,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("hypot", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Element-wise arc tangent of x1/x2 choosing the quadrant correctly.
- ///
- /// The quadrant (i.e., branch) is chosen so that arctan2(x1, x2) is
- /// the signed angle in radians between the ray ending at the origin and
- /// passing through the point (1,0), and the ray ending at the origin and
- /// passing through the point (x2, x1).
- /// (Note the role reversal: the
- /// “y-coordinate” is the first function parameter, the “x-coordinate”
- /// is the second.) By IEEE convention, this function is defined for
- /// x2 = +/-0 and for either or both of x1 and x2 = +/-inf (see
- /// Notes for specific values).
- ///
- /// This function is not defined for complex-valued arguments; for the
- /// so-called argument of complex values, use angle.
- ///
- /// Notes
- ///
- /// arctan2 is identical to the atan2 function of the underlying
- /// C library.
- /// The following special values are defined in the C
- /// standard: [1]
- ///
- /// Note that +0 and -0 are distinct floating point numbers, as are +inf
- /// and -inf.
- ///
- /// References
- ///
- ///
- /// x-coordinates.
- /// x2 must be broadcastable to match the shape of
- /// x1 or vice versa.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Array of angles in radians, in the range [-pi, pi].
- ///
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray arctan2(NDarray x2, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x2,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("arctan2", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Convert angles from radians to degrees.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The corresponding degree values; if out was supplied this is a
- /// reference to it.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray degrees(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("degrees", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Convert angles from degrees to radians.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The corresponding radian values.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray radians(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("radians", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Unwrap by changing deltas between values to 2*pi complement.
- ///
- /// Unwrap radian phase p by changing absolute jumps greater than
- /// discont to their 2*pi complement along the given axis.
- ///
- /// Notes
- ///
- /// If the discontinuity in p is smaller than pi, but larger than
- /// discont, no unwrapping is done because taking the 2*pi complement
- /// would only make the discontinuity larger.
- ///
- ///
- /// Maximum discontinuity between values, default is pi.
- ///
- ///
- /// Axis along which unwrap will operate, default is the last axis.
- ///
- ///
- /// Output array.
- ///
- public NDarray unwrap(float? discont = 3.141592653589793f, int? axis = -1)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (discont!=3.141592653589793f) kwargs["discont"]=ToPython(discont);
- if (axis!=-1) kwargs["axis"]=ToPython(axis);
- dynamic py = __self__.InvokeMethod("unwrap", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Convert angles from degrees to radians.
- ///
- /// Notes
- ///
- /// deg2rad(x) is x * pi / 180.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The corresponding angle in radians.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray deg2rad(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("deg2rad", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Convert angles from radians to degrees.
- ///
- /// Notes
- ///
- /// rad2deg(x) is 180 * x / pi.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The corresponding angle in degrees.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray rad2deg(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("rad2deg", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Hyperbolic sine, element-wise.
- ///
- /// Equivalent to 1/2 * (np.exp(x) - np.exp(-x)) or
- /// -1j * np.sin(1j*x).
- ///
- /// Notes
- ///
- /// If out is provided, the function writes the result into it,
- /// and returns a reference to out.
- /// (See Examples)
- ///
- /// References
- ///
- /// M.
- /// Abramowitz and I.
- /// A.
- /// Stegun, Handbook of Mathematical Functions.
- ///
- /// New York, NY: Dover, 1972, pg.
- /// 83.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The corresponding hyperbolic sine values.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray sinh(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("sinh", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Hyperbolic cosine, element-wise.
- ///
- /// Equivalent to 1/2 * (np.exp(x) + np.exp(-x)) and np.cos(1j*x).
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Output array of same shape as x.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray cosh(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("cosh", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Compute hyperbolic tangent element-wise.
- ///
- /// Equivalent to np.sinh(x)/np.cosh(x) or -1j * np.tan(1j*x).
- ///
- /// Notes
- ///
- /// If out is provided, the function writes the result into it,
- /// and returns a reference to out.
- /// (See Examples)
- ///
- /// References
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The corresponding hyperbolic tangent values.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray tanh(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("tanh", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Inverse hyperbolic sine element-wise.
- ///
- /// Notes
- ///
- /// arcsinh is a multivalued function: for each x there are infinitely
- /// many numbers z such that sinh(z) = x.
- /// The convention is to return the
- /// z whose imaginary part lies in [-pi/2, pi/2].
- ///
- /// For real-valued input data types, arcsinh always returns real output.
- ///
- /// For each value that cannot be expressed as a real number or infinity, it
- /// returns nan and sets the invalid floating point error flag.
- ///
- /// For complex-valued input, arccos is a complex analytical function that
- /// has branch cuts [1j, infj] and [-1j, -infj] and is continuous from
- /// the right on the former and from the left on the latter.
- ///
- /// The inverse hyperbolic sine is also known as asinh or sinh^-1.
- ///
- /// References
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Array of the same shape as x.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray arcsinh(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("arcsinh", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Inverse hyperbolic cosine, element-wise.
- ///
- /// Notes
- ///
- /// arccosh is a multivalued function: for each x there are infinitely
- /// many numbers z such that cosh(z) = x.
- /// The convention is to return the
- /// z whose imaginary part lies in [-pi, pi] and the real part in
- /// [0, inf].
- ///
- /// For real-valued input data types, arccosh always returns real output.
- ///
- /// For each value that cannot be expressed as a real number or infinity, it
- /// yields nan and sets the invalid floating point error flag.
- ///
- /// For complex-valued input, arccosh is a complex analytical function that
- /// has a branch cut [-inf, 1] and is continuous from above on it.
- ///
- /// References
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Array of the same shape as x.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray arccosh(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("arccosh", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Inverse hyperbolic tangent element-wise.
- ///
- /// Notes
- ///
- /// arctanh is a multivalued function: for each x there are infinitely
- /// many numbers z such that tanh(z) = x.
- /// The convention is to return
- /// the z whose imaginary part lies in [-pi/2, pi/2].
- ///
- /// For real-valued input data types, arctanh always returns real output.
- ///
- /// For each value that cannot be expressed as a real number or infinity,
- /// it yields nan and sets the invalid floating point error flag.
- ///
- /// For complex-valued input, arctanh is a complex analytical function
- /// that has branch cuts [-1, -inf] and [1, inf] and is continuous from
- /// above on the former and from below on the latter.
- ///
- /// The inverse hyperbolic tangent is also known as atanh or tanh^-1.
- ///
- /// References
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Array of the same shape as x.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray arctanh(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("arctanh", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Evenly round to the given number of decimals.
- ///
- /// Notes
- ///
- /// For values exactly halfway between rounded decimal values, NumPy
- /// rounds to the nearest even value.
- /// Thus 1.5 and 2.5 round to 2.0,
- /// -0.5 and 0.5 round to 0.0, etc.
- /// Results may also be surprising due
- /// to the inexact representation of decimal fractions in the IEEE
- /// floating point standard [1] and errors introduced when scaling
- /// by powers of ten.
- ///
- /// References
- ///
- ///
- /// Number of decimal places to round to (default: 0).
- /// If
- /// decimals is negative, it specifies the number of positions to
- /// the left of the decimal point.
- ///
- ///
- /// Alternative output array in which to place the result.
- /// It must have
- /// the same shape as the expected output, but the type of the output
- /// values will be cast if necessary.
- /// See doc.ufuncs (Section
- /// “Output arguments”) for details.
- ///
- ///
- /// An array of the same type as a, containing the rounded values.
- ///
- /// Unless out was specified, a new array is created.
- /// A reference to
- /// the result is returned.
- ///
- /// The real and imaginary parts of complex numbers are rounded
- /// separately.
- /// The result of rounding a float is a float.
- ///
- public NDarray around(int? decimals = 0, NDarray @out = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (decimals!=0) kwargs["decimals"]=ToPython(decimals);
- if (@out!=null) kwargs["out"]=ToPython(@out);
- dynamic py = __self__.InvokeMethod("around", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Round elements of the array to the nearest integer.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Output array is same shape and type as x.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray rint(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("rint", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Round to nearest integer towards zero.
- ///
- /// Round an array of floats element-wise to nearest integer towards zero.
- ///
- /// The rounded values are returned as floats.
- ///
- ///
- /// Output array
- ///
- ///
- /// The array of rounded numbers
- ///
- public NDarray fix(NDarray y = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (y!=null) kwargs["y"]=ToPython(y);
- dynamic py = __self__.InvokeMethod("fix", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the floor of the input, element-wise.
- ///
- /// The floor of the scalar x is the largest integer i, such that
- /// i <= x.
- /// It is often denoted as .
- ///
- /// Notes
- ///
- /// Some spreadsheet programs calculate the “floor-towards-zero”, in other
- /// words floor(-2.5) == -2. NumPy instead uses the definition of
- /// floor where floor(-2.5) == -3.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The floor of each element in x.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray floor(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("floor", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the ceiling of the input, element-wise.
- ///
- /// The ceil of the scalar x is the smallest integer i, such that
- /// i >= x.
- /// It is often denoted as .
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The ceiling of each element in x, with float dtype.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray ceil(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("ceil", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the truncated value of the input, element-wise.
- ///
- /// The truncated value of the scalar x is the nearest integer i which
- /// is closer to zero than x is.
- /// In short, the fractional part of the
- /// signed number x is discarded.
- ///
- /// Notes
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The truncated value of each element in x.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray trunc(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("trunc", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the product of array elements over a given axis.
- ///
- /// Notes
- ///
- /// Arithmetic is modular when using integer types, and no error is
- /// raised on overflow.
- /// That means that, on a 32-bit platform:
- ///
- /// The product of an empty array is the neutral element 1:
- ///
- ///
- /// Axis or axes along which a product is performed.
- /// The default,
- /// axis=None, will calculate the product of all the elements in the
- /// input array.
- /// If axis is negative it counts from the last to the
- /// first axis.
- ///
- /// If axis is a tuple of ints, a product is performed on all of the
- /// axes specified in the tuple instead of a single axis or all the
- /// axes as before.
- ///
- ///
- /// The type of the returned array, as well as of the accumulator in
- /// which the elements are multiplied.
- /// The dtype of a is used by
- /// default unless a has an integer dtype of less precision than the
- /// default platform integer.
- /// In that case, if a is signed then the
- /// platform integer is used while if a is unsigned then an unsigned
- /// integer of the same precision as the platform integer is used.
- ///
- ///
- /// Alternative output array in which to place the result.
- /// It must have
- /// the same shape as the expected output, but the type of the output
- /// values will be cast if necessary.
- ///
- ///
- /// If this is set to True, the axes which are reduced are left in the
- /// result as dimensions with size one.
- /// With this option, the result
- /// will broadcast correctly against the input array.
- ///
- /// If the default value is passed, then keepdims will not be
- /// passed through to the prod method of sub-classes of
- /// ndarray, however any non-default value will be.
- /// If the
- /// sub-class’ method does not implement keepdims any
- /// exceptions will be raised.
- ///
- ///
- /// The starting value for this product.
- /// See reduce for details.
- ///
- ///
- /// An array shaped as a but with the specified axis removed.
- ///
- /// Returns a reference to out if specified.
- ///
- public NDarray prod(Axis axis = null, Dtype dtype = null, NDarray @out = null, bool? keepdims = null, ValueType initial = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- if (dtype!=null) kwargs["dtype"]=ToPython(dtype);
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (keepdims!=null) kwargs["keepdims"]=ToPython(keepdims);
- if (initial!=null) kwargs["initial"]=ToPython(initial);
- dynamic py = __self__.InvokeMethod("prod", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Sum of array elements over a given axis.
- ///
- /// Notes
- ///
- /// Arithmetic is modular when using integer types, and no error is
- /// raised on overflow.
- ///
- /// The sum of an empty array is the neutral element 0:
- ///
- ///
- /// Axis or axes along which a sum is performed.
- /// The default,
- /// axis=None, will sum all of the elements of the input array.
- /// If
- /// axis is negative it counts from the last to the first axis.
- ///
- /// If axis is a tuple of ints, a sum is performed on all of the axes
- /// specified in the tuple instead of a single axis or all the axes as
- /// before.
- ///
- ///
- /// The type of the returned array and of the accumulator in which the
- /// elements are summed.
- /// The dtype of a is used by default unless a
- /// has an integer dtype of less precision than the default platform
- /// integer.
- /// In that case, if a is signed then the platform integer
- /// is used while if a is unsigned then an unsigned integer of the
- /// same precision as the platform integer is used.
- ///
- ///
- /// Alternative output array in which to place the result.
- /// It must have
- /// the same shape as the expected output, but the type of the output
- /// values will be cast if necessary.
- ///
- ///
- /// If this is set to True, the axes which are reduced are left
- /// in the result as dimensions with size one.
- /// With this option,
- /// the result will broadcast correctly against the input array.
- ///
- /// If the default value is passed, then keepdims will not be
- /// passed through to the sum method of sub-classes of
- /// ndarray, however any non-default value will be.
- /// If the
- /// sub-class’ method does not implement keepdims any
- /// exceptions will be raised.
- ///
- ///
- /// Starting value for the sum.
- /// See reduce for details.
- ///
- ///
- /// An array with the same shape as a, with the specified
- /// axis removed.
- /// If a is a 0-d array, or if axis is None, a scalar
- /// is returned.
- /// If an output array is specified, a reference to
- /// out is returned.
- ///
- public NDarray sum(Axis axis = null, Dtype dtype = null, NDarray @out = null, bool? keepdims = null, ValueType initial = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- if (dtype!=null) kwargs["dtype"]=ToPython(dtype);
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (keepdims!=null) kwargs["keepdims"]=ToPython(keepdims);
- if (initial!=null) kwargs["initial"]=ToPython(initial);
- dynamic py = __self__.InvokeMethod("sum", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the product of array elements over a given axis treating Not a
- /// Numbers (NaNs) as ones.
- ///
- /// One is returned for slices that are all-NaN or empty.
- ///
- ///
- /// Axis or axes along which the product is computed.
- /// The default is to compute
- /// the product of the flattened array.
- ///
- ///
- /// The type of the returned array and of the accumulator in which the
- /// elements are summed.
- /// By default, the dtype of a is used.
- /// An
- /// exception is when a has an integer type with less precision than
- /// the platform (u)intp.
- /// In that case, the default will be either
- /// (u)int32 or (u)int64 depending on whether the platform is 32 or 64
- /// bits.
- /// For inexact inputs, dtype must be inexact.
- ///
- ///
- /// Alternate output array in which to place the result.
- /// The default
- /// is None.
- /// If provided, it must have the same shape as the
- /// expected output, but the type will be cast if necessary.
- /// See
- /// doc.ufuncs for details.
- /// The casting of NaN to integer can yield
- /// unexpected results.
- ///
- ///
- /// If True, the axes which are reduced are left in the result as
- /// dimensions with size one.
- /// With this option, the result will
- /// broadcast correctly against the original arr.
- ///
- ///
- /// A new array holding the result is returned unless out is
- /// specified, in which case it is returned.
- ///
- public NDarray nanprod(Axis axis = null, Dtype dtype = null, NDarray @out = null, bool? keepdims = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- if (dtype!=null) kwargs["dtype"]=ToPython(dtype);
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (keepdims!=null) kwargs["keepdims"]=ToPython(keepdims);
- dynamic py = __self__.InvokeMethod("nanprod", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the sum of array elements over a given axis treating Not a
- /// Numbers (NaNs) as zero.
- ///
- /// In NumPy versions <= 1.9.0 Nan is returned for slices that are all-NaN or
- /// empty.
- /// In later versions zero is returned.
- ///
- /// Notes
- ///
- /// If both positive and negative infinity are present, the sum will be Not
- /// A Number (NaN).
- ///
- ///
- /// Axis or axes along which the sum is computed.
- /// The default is to compute the
- /// sum of the flattened array.
- ///
- ///
- /// The type of the returned array and of the accumulator in which the
- /// elements are summed.
- /// By default, the dtype of a is used.
- /// An
- /// exception is when a has an integer type with less precision than
- /// the platform (u)intp.
- /// In that case, the default will be either
- /// (u)int32 or (u)int64 depending on whether the platform is 32 or 64
- /// bits.
- /// For inexact inputs, dtype must be inexact.
- ///
- ///
- /// Alternate output array in which to place the result.
- /// The default
- /// is None.
- /// If provided, it must have the same shape as the
- /// expected output, but the type will be cast if necessary.
- /// See
- /// doc.ufuncs for details.
- /// The casting of NaN to integer can yield
- /// unexpected results.
- ///
- ///
- /// If this is set to True, the axes which are reduced are left
- /// in the result as dimensions with size one.
- /// With this option,
- /// the result will broadcast correctly against the original a.
- ///
- /// If the value is anything but the default, then
- /// keepdims will be passed through to the mean or sum methods
- /// of sub-classes of ndarray.
- /// If the sub-classes methods
- /// does not implement keepdims any exceptions will be raised.
- ///
- ///
- /// A new array holding the result is returned unless out is
- /// specified, in which it is returned.
- /// The result has the same
- /// size as a, and the same shape as a if axis is not None
- /// or a is a 1-d array.
- ///
- public NDarray nansum(Axis axis = null, Dtype dtype = null, NDarray @out = null, bool? keepdims = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- if (dtype!=null) kwargs["dtype"]=ToPython(dtype);
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (keepdims!=null) kwargs["keepdims"]=ToPython(keepdims);
- dynamic py = __self__.InvokeMethod("nansum", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the cumulative product of elements along a given axis.
- ///
- /// Notes
- ///
- /// Arithmetic is modular when using integer types, and no error is
- /// raised on overflow.
- ///
- ///
- /// Axis along which the cumulative product is computed.
- /// By default
- /// the input is flattened.
- ///
- ///
- /// Type of the returned array, as well as of the accumulator in which
- /// the elements are multiplied.
- /// If dtype is not specified, it
- /// defaults to the dtype of a, unless a has an integer dtype with
- /// a precision less than that of the default platform integer.
- /// In
- /// that case, the default platform integer is used instead.
- ///
- ///
- /// Alternative output array in which to place the result.
- /// It must
- /// have the same shape and buffer length as the expected output
- /// but the type of the resulting values will be cast if necessary.
- ///
- ///
- /// A new array holding the result is returned unless out is
- /// specified, in which case a reference to out is returned.
- ///
- public NDarray cumprod(int? axis = null, Dtype dtype = null, NDarray @out = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- if (dtype!=null) kwargs["dtype"]=ToPython(dtype);
- if (@out!=null) kwargs["out"]=ToPython(@out);
- dynamic py = __self__.InvokeMethod("cumprod", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the cumulative sum of the elements along a given axis.
- ///
- /// Notes
- ///
- /// Arithmetic is modular when using integer types, and no error is
- /// raised on overflow.
- ///
- ///
- /// Axis along which the cumulative sum is computed.
- /// The default
- /// (None) is to compute the cumsum over the flattened array.
- ///
- ///
- /// Type of the returned array and of the accumulator in which the
- /// elements are summed.
- /// If dtype is not specified, it defaults
- /// to the dtype of a, unless a has an integer dtype with a
- /// precision less than that of the default platform integer.
- /// In
- /// that case, the default platform integer is used.
- ///
- ///
- /// Alternative output array in which to place the result.
- /// It must
- /// have the same shape and buffer length as the expected output
- /// but the type will be cast if necessary.
- /// See doc.ufuncs
- /// (Section “Output arguments”) for more details.
- ///
- ///
- /// A new array holding the result is returned unless out is
- /// specified, in which case a reference to out is returned.
- /// The
- /// result has the same size as a, and the same shape as a if
- /// axis is not None or a is a 1-d array.
- ///
- public NDarray cumsum(int? axis = null, Dtype dtype = null, NDarray @out = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- if (dtype!=null) kwargs["dtype"]=ToPython(dtype);
- if (@out!=null) kwargs["out"]=ToPython(@out);
- dynamic py = __self__.InvokeMethod("cumsum", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the cumulative product of array elements over a given axis treating Not a
- /// Numbers (NaNs) as one.
- /// The cumulative product does not change when NaNs are
- /// encountered and leading NaNs are replaced by ones.
- ///
- /// Ones are returned for slices that are all-NaN or empty.
- ///
- ///
- /// Axis along which the cumulative product is computed.
- /// By default
- /// the input is flattened.
- ///
- ///
- /// Type of the returned array, as well as of the accumulator in which
- /// the elements are multiplied.
- /// If dtype is not specified, it
- /// defaults to the dtype of a, unless a has an integer dtype with
- /// a precision less than that of the default platform integer.
- /// In
- /// that case, the default platform integer is used instead.
- ///
- ///
- /// Alternative output array in which to place the result.
- /// It must
- /// have the same shape and buffer length as the expected output
- /// but the type of the resulting values will be cast if necessary.
- ///
- ///
- /// A new array holding the result is returned unless out is
- /// specified, in which case it is returned.
- ///
- public NDarray nancumprod(int? axis = null, Dtype dtype = null, NDarray @out = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- if (dtype!=null) kwargs["dtype"]=ToPython(dtype);
- if (@out!=null) kwargs["out"]=ToPython(@out);
- dynamic py = __self__.InvokeMethod("nancumprod", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the cumulative sum of array elements over a given axis treating Not a
- /// Numbers (NaNs) as zero.
- /// The cumulative sum does not change when NaNs are
- /// encountered and leading NaNs are replaced by zeros.
- ///
- /// Zeros are returned for slices that are all-NaN or empty.
- ///
- ///
- /// Axis along which the cumulative sum is computed.
- /// The default
- /// (None) is to compute the cumsum over the flattened array.
- ///
- ///
- /// Type of the returned array and of the accumulator in which the
- /// elements are summed.
- /// If dtype is not specified, it defaults
- /// to the dtype of a, unless a has an integer dtype with a
- /// precision less than that of the default platform integer.
- /// In
- /// that case, the default platform integer is used.
- ///
- ///
- /// Alternative output array in which to place the result.
- /// It must
- /// have the same shape and buffer length as the expected output
- /// but the type will be cast if necessary.
- /// See doc.ufuncs
- /// (Section “Output arguments”) for more details.
- ///
- ///
- /// A new array holding the result is returned unless out is
- /// specified, in which it is returned.
- /// The result has the same
- /// size as a, and the same shape as a if axis is not None
- /// or a is a 1-d array.
- ///
- public NDarray nancumsum(int? axis = null, Dtype dtype = null, NDarray @out = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- if (dtype!=null) kwargs["dtype"]=ToPython(dtype);
- if (@out!=null) kwargs["out"]=ToPython(@out);
- dynamic py = __self__.InvokeMethod("nancumsum", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Calculate the n-th discrete difference along the given axis.
- ///
- /// The first difference is given by out[n] = a[n+1] - a[n] along
- /// the given axis, higher differences are calculated by using diff
- /// recursively.
- ///
- /// Notes
- ///
- /// Type is preserved for boolean arrays, so the result will contain
- /// False when consecutive elements are the same and True when they
- /// differ.
- ///
- /// For unsigned integer arrays, the results will also be unsigned.
- /// This
- /// should not be surprising, as the result is consistent with
- /// calculating the difference directly:
- ///
- /// If this is not desirable, then the array should be cast to a larger
- /// integer type first:
- ///
- ///
- /// The number of times values are differenced.
- /// If zero, the input
- /// is returned as-is.
- ///
- ///
- /// The axis along which the difference is taken, default is the
- /// last axis.
- ///
- ///
- /// Values to prepend or append to “a” along axis prior to
- /// performing the difference.
- /// Scalar values are expanded to
- /// arrays with length 1 in the direction of axis and the shape
- /// of the input array in along all other axes.
- /// Otherwise the
- /// dimension and shape must match “a” except along axis.
- ///
- ///
- /// Values to prepend or append to “a” along axis prior to
- /// performing the difference.
- /// Scalar values are expanded to
- /// arrays with length 1 in the direction of axis and the shape
- /// of the input array in along all other axes.
- /// Otherwise the
- /// dimension and shape must match “a” except along axis.
- ///
- ///
- /// The n-th differences.
- /// The shape of the output is the same as a
- /// except along axis where the dimension is smaller by n.
- /// The
- /// type of the output is the same as the type of the difference
- /// between any two elements of a.
- /// This is the same as the type of
- /// a in most cases.
- /// A notable exception is datetime64, which
- /// results in a timedelta64 output array.
- ///
- public NDarray diff(int? n = 1, int? axis = -1, NDarray append = null, NDarray prepend = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (n!=1) kwargs["n"]=ToPython(n);
- if (axis!=-1) kwargs["axis"]=ToPython(axis);
- if (append!=null) kwargs["append"]=ToPython(append);
- if (prepend!=null) kwargs["prepend"]=ToPython(prepend);
- dynamic py = __self__.InvokeMethod("diff", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// The differences between consecutive elements of an array.
- ///
- /// Notes
- ///
- /// When applied to masked arrays, this function drops the mask information
- /// if the to_begin and/or to_end parameters are used.
- ///
- ///
- /// Number(s) to append at the end of the returned differences.
- ///
- ///
- /// Number(s) to prepend at the beginning of the returned differences.
- ///
- ///
- /// The differences.
- /// Loosely, this is ary.flat[1:] - ary.flat[:-1].
- ///
- public NDarray ediff1d(NDarray to_end = null, NDarray to_begin = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (to_end!=null) kwargs["to_end"]=ToPython(to_end);
- if (to_begin!=null) kwargs["to_begin"]=ToPython(to_begin);
- dynamic py = __self__.InvokeMethod("ediff1d", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the cross product of two (arrays of) vectors.
- ///
- /// The cross product of a and b in is a vector perpendicular
- /// to both a and b.
- /// If a and b are arrays of vectors, the vectors
- /// are defined by the last axis of a and b by default, and these axes
- /// can have dimensions 2 or 3.
- /// Where the dimension of either a or b is
- /// 2, the third component of the input vector is assumed to be zero and the
- /// cross product calculated accordingly.
- /// In cases where both input vectors
- /// have dimension 2, the z-component of the cross product is returned.
- ///
- /// Notes
- ///
- /// Supports full broadcasting of the inputs.
- ///
- ///
- /// Components of the second vector(s).
- ///
- ///
- /// Axis of a that defines the vector(s).
- /// By default, the last axis.
- ///
- ///
- /// Axis of b that defines the vector(s).
- /// By default, the last axis.
- ///
- ///
- /// Axis of c containing the cross product vector(s).
- /// Ignored if
- /// both input vectors have dimension 2, as the return is scalar.
- ///
- /// By default, the last axis.
- ///
- ///
- /// If defined, the axis of a, b and c that defines the vector(s)
- /// and cross product(s).
- /// Overrides axisa, axisb and axisc.
- ///
- ///
- /// Vector cross product(s).
- ///
- public NDarray cross(NDarray b, int? axisa = -1, int? axisb = -1, int? axisc = -1, int? axis = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- b,
- });
- var kwargs=new PyDict();
- if (axisa!=-1) kwargs["axisa"]=ToPython(axisa);
- if (axisb!=-1) kwargs["axisb"]=ToPython(axisb);
- if (axisc!=-1) kwargs["axisc"]=ToPython(axisc);
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- dynamic py = __self__.InvokeMethod("cross", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Integrate along the given axis using the composite trapezoidal rule.
- ///
- /// Integrate y (x) along given axis.
- ///
- /// Notes
- ///
- /// Image [2] illustrates trapezoidal rule – y-axis locations of points
- /// will be taken from y array, by default x-axis distances between
- /// points will be 1.0, alternatively they can be provided with x array
- /// or with dx scalar.
- /// Return value will be equal to combined area under
- /// the red lines.
- ///
- /// References
- ///
- ///
- /// The sample points corresponding to the y values.
- /// If x is None,
- /// the sample points are assumed to be evenly spaced dx apart.
- /// The
- /// default is None.
- ///
- ///
- /// The spacing between sample points when x is None.
- /// The default is 1.
- ///
- ///
- /// The axis along which to integrate.
- ///
- ///
- /// Definite integral as approximated by trapezoidal rule.
- ///
- public float trapz(NDarray x = null, float? dx = 1.0f, int? axis = -1)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (x!=null) kwargs["x"]=ToPython(x);
- if (dx!=1.0f) kwargs["dx"]=ToPython(dx);
- if (axis!=-1) kwargs["axis"]=ToPython(axis);
- dynamic py = __self__.InvokeMethod("trapz", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Calculate the exponential of all elements in the input array.
- ///
- /// Notes
- ///
- /// The irrational number e is also known as Euler’s number.
- /// It is
- /// approximately 2.718281, and is the base of the natural logarithm,
- /// ln (this means that, if ,
- /// then . For real input, exp(x) is always positive.
- ///
- /// For complex arguments, x = a + ib, we can write
- /// . The first term, , is already
- /// known (it is the real argument, described above).
- /// The second term,
- /// , is , a function with
- /// magnitude 1 and a periodic phase.
- ///
- /// References
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Output array, element-wise exponential of x.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray exp(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("exp", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Calculate exp(x) - 1 for all elements in the array.
- ///
- /// Notes
- ///
- /// This function provides greater precision than exp(x) - 1
- /// for small values of x.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Element-wise exponential minus one: out = exp(x) - 1.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray expm1(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("expm1", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Calculate 2**p for all p in the input array.
- ///
- /// Notes
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Element-wise 2 to the power x.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray exp2(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("exp2", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Natural logarithm, element-wise.
- ///
- /// The natural logarithm log is the inverse of the exponential function,
- /// so that log(exp(x)) = x.
- /// The natural logarithm is logarithm in base
- /// e.
- ///
- /// Notes
- ///
- /// Logarithm is a multivalued function: for each x there is an infinite
- /// number of z such that exp(z) = x.
- /// The convention is to return the
- /// z whose imaginary part lies in [-pi, pi].
- ///
- /// For real-valued input data types, log always returns real output.
- /// For
- /// each value that cannot be expressed as a real number or infinity, it
- /// yields nan and sets the invalid floating point error flag.
- ///
- /// For complex-valued input, log is a complex analytical function that
- /// has a branch cut [-inf, 0] and is continuous from above on it.
- /// log
- /// handles the floating-point negative zero as an infinitesimal negative
- /// number, conforming to the C99 standard.
- ///
- /// References
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The natural logarithm of x, element-wise.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray log(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("log", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the base 10 logarithm of the input array, element-wise.
- ///
- /// Notes
- ///
- /// Logarithm is a multivalued function: for each x there is an infinite
- /// number of z such that 10**z = x.
- /// The convention is to return the
- /// z whose imaginary part lies in [-pi, pi].
- ///
- /// For real-valued input data types, log10 always returns real output.
- ///
- /// For each value that cannot be expressed as a real number or infinity,
- /// it yields nan and sets the invalid floating point error flag.
- ///
- /// For complex-valued input, log10 is a complex analytical function that
- /// has a branch cut [-inf, 0] and is continuous from above on it.
- ///
- /// log10 handles the floating-point negative zero as an infinitesimal
- /// negative number, conforming to the C99 standard.
- ///
- /// References
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The logarithm to the base 10 of x, element-wise.
- /// NaNs are
- /// returned where x is negative.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray log10(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("log10", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Base-2 logarithm of x.
- ///
- /// Notes
- ///
- /// Logarithm is a multivalued function: for each x there is an infinite
- /// number of z such that 2**z = x.
- /// The convention is to return the z
- /// whose imaginary part lies in [-pi, pi].
- ///
- /// For real-valued input data types, log2 always returns real output.
- ///
- /// For each value that cannot be expressed as a real number or infinity,
- /// it yields nan and sets the invalid floating point error flag.
- ///
- /// For complex-valued input, log2 is a complex analytical function that
- /// has a branch cut [-inf, 0] and is continuous from above on it.
- /// log2
- /// handles the floating-point negative zero as an infinitesimal negative
- /// number, conforming to the C99 standard.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Base-2 logarithm of x.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray log2(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("log2", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the natural logarithm of one plus the input array, element-wise.
- ///
- /// Calculates log(1 + x).
- ///
- /// Notes
- ///
- /// For real-valued input, log1p is accurate also for x so small
- /// that 1 + x == 1 in floating-point accuracy.
- ///
- /// Logarithm is a multivalued function: for each x there is an infinite
- /// number of z such that exp(z) = 1 + x.
- /// The convention is to return
- /// the z whose imaginary part lies in [-pi, pi].
- ///
- /// For real-valued input data types, log1p always returns real output.
- ///
- /// For each value that cannot be expressed as a real number or infinity,
- /// it yields nan and sets the invalid floating point error flag.
- ///
- /// For complex-valued input, log1p is a complex analytical function that
- /// has a branch cut [-inf, -1] and is continuous from above on it.
- ///
- /// log1p handles the floating-point negative zero as an infinitesimal
- /// negative number, conforming to the C99 standard.
- ///
- /// References
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Natural logarithm of 1 + x, element-wise.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray log1p(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("log1p", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Logarithm of the sum of exponentiations of the inputs.
- ///
- /// Calculates log(exp(x1) + exp(x2)).
- /// This function is useful in
- /// statistics where the calculated probabilities of events may be so small
- /// as to exceed the range of normal floating point numbers.
- /// In such cases
- /// the logarithm of the calculated probability is stored.
- /// This function
- /// allows adding probabilities stored in such a fashion.
- ///
- /// Notes
- ///
- ///
- /// Input values.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Logarithm of exp(x1) + exp(x2).
- ///
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray logaddexp(NDarray x1, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x1,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("logaddexp", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Logarithm of the sum of exponentiations of the inputs in base-2.
- ///
- /// Calculates log2(2**x1 + 2**x2).
- /// This function is useful in machine
- /// learning when the calculated probabilities of events may be so small as
- /// to exceed the range of normal floating point numbers.
- /// In such cases
- /// the base-2 logarithm of the calculated probability can be used instead.
- ///
- /// This function allows adding probabilities stored in such a fashion.
- ///
- /// Notes
- ///
- ///
- /// Input values.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Base-2 logarithm of 2**x1 + 2**x2.
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray logaddexp2(NDarray x1, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x1,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("logaddexp2", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the sinc function.
- ///
- /// The sinc function is .
- ///
- /// Notes
- ///
- /// sinc(0) is the limit value 1.
- ///
- /// The name sinc is short for “sine cardinal” or “sinus cardinalis”.
- ///
- /// The sinc function is used in various signal processing applications,
- /// including in anti-aliasing, in the construction of a Lanczos resampling
- /// filter, and in interpolation.
- ///
- /// For bandlimited interpolation of discrete-time signals, the ideal
- /// interpolation kernel is proportional to the sinc function.
- ///
- /// References
- ///
- ///
- /// sinc(x), which has the same shape as the input.
- ///
- public NDarray sinc()
- {
- //auto-generated code, do not change
- var __self__=self;
- dynamic py = __self__.InvokeMethod("sinc");
- return ToCsharp(py);
- }
-
- ///
- /// Returns element-wise True where signbit is set (less than zero).
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Output array, or reference to out if that was supplied.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray signbit(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("signbit", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Change the sign of x1 to that of x2, element-wise.
- ///
- /// If both arguments are arrays or sequences, they have to be of the same
- /// length.
- /// If x2 is a scalar, its sign will be copied to all elements of
- /// x1.
- ///
- ///
- /// The sign of x2 is copied to x1.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The values of x1 with the sign of x2.
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray copysign(NDarray x2, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x2,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("copysign", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Decompose the elements of x into mantissa and twos exponent.
- ///
- /// Returns (mantissa, exponent), where x = mantissa * 2**exponent`.
- /// The mantissa is lies in the open interval(-1, 1), while the twos
- /// exponent is a signed integer.
- ///
- /// Notes
- ///
- /// Complex dtypes are not supported, they will raise a TypeError.
- ///
- ///
- /// Output array for the mantissa.
- /// Must have the same shape as x.
- ///
- ///
- /// Output array for the exponent.
- /// Must have the same shape as x.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// A tuple of:
- /// mantissa
- /// Floating values between -1 and 1.
- /// This is a scalar if x is a scalar.
- /// exponent
- /// Integer exponents of 2.
- /// This is a scalar if x is a scalar.
- ///
- public (NDarray, NDarray) frexp(NDarray out1 = null, NDarray out2 = null, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (out1!=null) kwargs["out1"]=ToPython(out1);
- if (out2!=null) kwargs["out2"]=ToPython(out2);
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("frexp", pyargs, kwargs);
- return (ToCsharp(py[0]), ToCsharp(py[1]));
- }
-
- ///
- /// Returns x1 * 2**x2, element-wise.
- ///
- /// The mantissas x1 and twos exponents x2 are used to construct
- /// floating point numbers x1 * 2**x2.
- ///
- /// Notes
- ///
- /// Complex dtypes are not supported, they will raise a TypeError.
- ///
- /// ldexp is useful as the inverse of frexp, if used by itself it is
- /// more clear to simply use the expression x1 * 2**x2.
- ///
- ///
- /// Array of twos exponents.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The result of x1 * 2**x2.
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray ldexp(NDarray x2, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x2,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("ldexp", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the next floating-point value after x1 towards x2, element-wise.
- ///
- ///
- /// The direction where to look for the next representable value of x1.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The next representable values of x1 in the direction of x2.
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray nextafter(NDarray x2, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x2,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("nextafter", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the distance between x and the nearest adjacent number.
- ///
- /// Notes
- ///
- /// It can be considered as a generalization of EPS:
- /// spacing(np.float64(1)) == np.finfo(np.float64).eps, and there
- /// should not be any representable number between x + spacing(x) and
- /// x for any finite x.
- ///
- /// Spacing of +- inf and NaN is NaN.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The spacing of values of x.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray spacing(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("spacing", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Returns the lowest common multiple of |x1| and |x2|
- ///
- ///
- /// Arrays of values
- ///
- ///
- /// The lowest common multiple of the absolute value of the inputs
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray lcm(NDarray x1)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x1,
- });
- var kwargs=new PyDict();
- dynamic py = __self__.InvokeMethod("lcm", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Returns the greatest common divisor of |x1| and |x2|
- ///
- ///
- /// Arrays of values
- ///
- ///
- /// The greatest common divisor of the absolute value of the inputs
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray gcd(NDarray x1)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x1,
- });
- var kwargs=new PyDict();
- dynamic py = __self__.InvokeMethod("gcd", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Add arguments element-wise.
- ///
- /// Notes
- ///
- /// Equivalent to x1 + x2 in terms of array broadcasting.
- ///
- ///
- /// The arrays to be added.
- /// If x1.shape != x2.shape, they must be
- /// broadcastable to a common shape (which may be the shape of one or
- /// the other).
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The sum of x1 and x2, element-wise.
- ///
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray @add(NDarray x1, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x1,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("add", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the reciprocal of the argument, element-wise.
- ///
- /// Calculates 1/x.
- ///
- /// Notes
- ///
- /// For integer arguments with absolute value larger than 1 the result is
- /// always zero because of the way Python handles integer division.
- /// For
- /// integer zero the result is an overflow.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Return array.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray reciprocal(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("reciprocal", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Numerical positive, element-wise.
- ///
- /// Notes
- ///
- /// Equivalent to x.copy(), but only defined for types that support
- /// arithmetic.
- ///
- ///
- /// Returned array or scalar: y = +x.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray positive()
- {
- //auto-generated code, do not change
- var __self__=self;
- dynamic py = __self__.InvokeMethod("positive");
- return ToCsharp(py);
- }
-
- ///
- /// Numerical negative, element-wise.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Returned array or scalar: y = -x.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray negative(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("negative", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Multiply arguments element-wise.
- ///
- /// Notes
- ///
- /// Equivalent to x1 * x2 in terms of array broadcasting.
- ///
- ///
- /// Input arrays to be multiplied.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The product of x1 and x2, element-wise.
- ///
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray multiply(NDarray x1, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x1,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("multiply", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Returns a true division of the inputs, element-wise.
- ///
- /// Instead of the Python traditional ‘floor division’, this returns a true
- /// division.
- /// True division adjusts the output type to present the best
- /// answer, regardless of input types.
- ///
- /// Notes
- ///
- /// The floor division operator // was added in Python 2.2 making
- /// // and / equivalent operators.
- /// The default floor division
- /// operation of / can be replaced by true division with from
- /// __future__ import division.
- ///
- /// In Python 3.0, // is the floor division operator and / the
- /// true division operator.
- /// The true_divide(x1, x2) function is
- /// equivalent to true division in Python.
- ///
- ///
- /// Divisor array.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray divide(NDarray x2, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x2,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("divide", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// First array elements raised to powers from second array, element-wise.
- ///
- /// Raise each base in x1 to the positionally-corresponding power in
- /// x2. x1 and x2 must be broadcastable to the same shape.
- /// Note that an
- /// integer type raised to a negative integer power will raise a ValueError.
- ///
- ///
- /// The exponents.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The bases in x1 raised to the exponents in x2.
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray power(NDarray x2, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x2,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("power", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Subtract arguments, element-wise.
- ///
- /// Notes
- ///
- /// Equivalent to x1 - x2 in terms of array broadcasting.
- ///
- ///
- /// The arrays to be subtracted from each other.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The difference of x1 and x2, element-wise.
- ///
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray subtract(NDarray x1, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x1,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("subtract", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Returns a true division of the inputs, element-wise.
- ///
- /// Instead of the Python traditional ‘floor division’, this returns a true
- /// division.
- /// True division adjusts the output type to present the best
- /// answer, regardless of input types.
- ///
- /// Notes
- ///
- /// The floor division operator // was added in Python 2.2 making
- /// // and / equivalent operators.
- /// The default floor division
- /// operation of / can be replaced by true division with from
- /// __future__ import division.
- ///
- /// In Python 3.0, // is the floor division operator and / the
- /// true division operator.
- /// The true_divide(x1, x2) function is
- /// equivalent to true division in Python.
- ///
- ///
- /// Divisor array.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray true_divide(NDarray x2, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x2,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("true_divide", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the largest integer smaller or equal to the division of the inputs.
- ///
- /// It is equivalent to the Python // operator and pairs with the
- /// Python % (remainder), function so that b = a % b + b * (a // b)
- /// up to roundoff.
- ///
- ///
- /// Denominator.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// y = floor(x1/x2)
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray floor_divide(NDarray x2, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x2,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("floor_divide", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// First array elements raised to powers from second array, element-wise.
- ///
- /// Raise each base in x1 to the positionally-corresponding power in x2.
- /// x1 and x2 must be broadcastable to the same shape.
- /// This differs from
- /// the power function in that integers, float16, and float32 are promoted to
- /// floats with a minimum precision of float64 so that the result is always
- /// inexact.
- /// The intent is that the function will return a usable result for
- /// negative powers and seldom overflow for positive powers.
- ///
- ///
- /// The exponents.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The bases in x1 raised to the exponents in x2.
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray float_power(NDarray x2, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x2,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("float_power", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the element-wise remainder of division.
- ///
- /// This is the NumPy implementation of the C library function fmod, the
- /// remainder has the same sign as the dividend x1. It is equivalent to
- /// the Matlab(TM) rem function and should not be confused with the
- /// Python modulus operator x1 % x2.
- ///
- /// Notes
- ///
- /// The result of the modulo operation for negative dividend and divisors
- /// is bound by conventions.
- /// For fmod, the sign of result is the sign of
- /// the dividend, while for remainder the sign of the result is the sign
- /// of the divisor.
- /// The fmod function is equivalent to the Matlab(TM)
- /// rem function.
- ///
- ///
- /// Divisor.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The remainder of the division of x1 by x2.
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray fmod(NDarray x2, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x2,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("fmod", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return element-wise remainder of division.
- ///
- /// Computes the remainder complementary to the floor_divide function.
- /// It is
- /// equivalent to the Python modulus operator``x1 % x2`` and has the same sign
- /// as the divisor x2. The MATLAB function equivalent to np.remainder
- /// is mod.
- ///
- /// Notes
- ///
- /// Returns 0 when x2 is 0 and both x1 and x2 are (arrays of)
- /// integers.
- ///
- ///
- /// Divisor array.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The element-wise remainder of the quotient floor_divide(x1, x2).
- ///
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray mod(NDarray x2, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x2,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("mod", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the fractional and integral parts of an array, element-wise.
- ///
- /// The fractional and integral parts are negative if the given number is
- /// negative.
- ///
- /// Notes
- ///
- /// For integer input the return values are floats.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// A tuple of:
- /// y1
- /// Fractional part of x.
- /// This is a scalar if x is a scalar.
- /// y2
- /// Integral part of x.
- /// This is a scalar if x is a scalar.
- ///
- public (NDarray, NDarray) modf(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("modf", pyargs, kwargs);
- return (ToCsharp(py[0]), ToCsharp(py[1]));
- }
-
- ///
- /// Return element-wise remainder of division.
- ///
- /// Computes the remainder complementary to the floor_divide function.
- /// It is
- /// equivalent to the Python modulus operator``x1 % x2`` and has the same sign
- /// as the divisor x2. The MATLAB function equivalent to np.remainder
- /// is mod.
- ///
- /// Notes
- ///
- /// Returns 0 when x2 is 0 and both x1 and x2 are (arrays of)
- /// integers.
- ///
- ///
- /// Divisor array.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The element-wise remainder of the quotient floor_divide(x1, x2).
- ///
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray remainder(NDarray x2, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x2,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("remainder", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return element-wise quotient and remainder simultaneously.
- ///
- /// np.divmod(x, y) is equivalent to (x // y, x % y), but faster
- /// because it avoids redundant work.
- /// It is used to implement the Python
- /// built-in function divmod on NumPy arrays.
- ///
- ///
- /// Divisor array.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// A tuple of:
- /// out1
- /// Element-wise quotient resulting from floor division.
- /// This is a scalar if both x1 and x2 are scalars.
- /// out2
- /// Element-wise remainder from floor division.
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public (NDarray, NDarray) divmod(NDarray x2, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x2,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("divmod", pyargs, kwargs);
- return (ToCsharp(py[0]), ToCsharp(py[1]));
- }
-
- ///
- /// Return the angle of the complex argument.
- ///
- ///
- /// Return angle in degrees if True, radians if False (default).
- ///
- ///
- /// The counterclockwise angle from the positive real axis on
- /// the complex plane, with dtype as numpy.float64.
- ///
- public NDarray angle(bool? deg = false)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (deg!=false) kwargs["deg"]=ToPython(deg);
- dynamic py = __self__.InvokeMethod("angle", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the complex conjugate, element-wise.
- ///
- /// The complex conjugate of a complex number is obtained by changing the
- /// sign of its imaginary part.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The complex conjugate of x, with same dtype as y.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray conj(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("conj", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Returns the discrete, linear convolution of two one-dimensional sequences.
- ///
- /// The convolution operator is often seen in signal processing, where it
- /// models the effect of a linear time-invariant system on a signal [1].
- /// In
- /// probability theory, the sum of two independent random variables is
- /// distributed according to the convolution of their individual
- /// distributions.
- ///
- /// If v is longer than a, the arrays are swapped before computation.
- ///
- /// Notes
- ///
- /// The discrete convolution operation is defined as
- ///
- /// It can be shown that a convolution in time/space
- /// is equivalent to the multiplication in the Fourier
- /// domain, after appropriate padding (padding is necessary to prevent
- /// circular convolution).
- /// Since multiplication is more efficient (faster)
- /// than convolution, the function scipy.signal.fftconvolve exploits the
- /// FFT to calculate the convolution of large data-sets.
- ///
- /// References
- ///
- ///
- /// Second one-dimensional input array.
- ///
- ///
- /// Discrete, linear convolution of a and v.
- ///
- public NDarray convolve(NDarray v, string mode = "full")
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- v,
- });
- var kwargs=new PyDict();
- if (mode!="full") kwargs["mode"]=ToPython(mode);
- dynamic py = __self__.InvokeMethod("convolve", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Clip (limit) the values in an array.
- ///
- /// Given an interval, values outside the interval are clipped to
- /// the interval edges.
- /// For example, if an interval of [0, 1]
- /// is specified, values smaller than 0 become 0, and values larger
- /// than 1 become 1.
- ///
- ///
- /// Minimum value.
- /// If None, clipping is not performed on lower
- /// interval edge.
- /// Not more than one of a_min and a_max may be
- /// None.
- ///
- ///
- /// Maximum value.
- /// If None, clipping is not performed on upper
- /// interval edge.
- /// Not more than one of a_min and a_max may be
- /// None.
- /// If a_min or a_max are array_like, then the three
- /// arrays will be broadcasted to match their shapes.
- ///
- ///
- /// The results will be placed in this array.
- /// It may be the input
- /// array for in-place clipping.
- /// out must be of the right shape
- /// to hold the output.
- /// Its type is preserved.
- ///
- ///
- /// An array with the elements of a, but where values
- /// < a_min are replaced with a_min, and those > a_max
- /// with a_max.
- ///
- public NDarray clip(NDarray a_min, NDarray a_max, NDarray @out = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- a_min,
- a_max,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- dynamic py = __self__.InvokeMethod("clip", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the non-negative square-root of an array, element-wise.
- ///
- /// Notes
- ///
- /// sqrt has–consistent with common convention–as its branch cut the
- /// real “interval” [-inf, 0), and is continuous from above on it.
- ///
- /// A branch cut is a curve in the complex plane across which a given
- /// complex function fails to be continuous.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// An array of the same shape as x, containing the positive
- /// square-root of each element in x.
- /// If any element in x is
- /// complex, a complex array is returned (and the square-roots of
- /// negative reals are calculated).
- /// If all of the elements in x
- /// are real, so is y, with negative elements returning nan.
- ///
- /// If out was provided, y is a reference to it.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray sqrt(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("sqrt", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the cube-root of an array, element-wise.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// An array of the same shape as x, containing the cube
- /// cube-root of each element in x.
- ///
- /// If out was provided, y is a reference to it.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray cbrt(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("cbrt", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the element-wise square of the input.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// Element-wise x*x, of the same shape and dtype as x.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray square(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("square", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Calculate the absolute value element-wise.
- ///
- /// np.abs is a shorthand for this function.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// An ndarray containing the absolute value of
- /// each element in x.
- /// For complex input, a + ib, the
- /// absolute value is .
- /// This is a scalar if x is a scalar.
- ///
- public NDarray absolute(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("absolute", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Compute the absolute values element-wise.
- ///
- /// This function returns the absolute values (positive magnitude) of the
- /// data in x.
- /// Complex values are not handled, use absolute to find the
- /// absolute values of complex data.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The absolute values of x, the returned values are always floats.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray fabs(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("fabs", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Returns an element-wise indication of the sign of a number.
- ///
- /// The sign function returns -1 if x < 0, 0 if x==0, 1 if x > 0.
- /// nan
- /// is returned for nan inputs.
- ///
- /// For complex inputs, the sign function returns
- /// sign(x.real) + 0j if x.real != 0 else sign(x.imag) + 0j.
- ///
- /// complex(nan, 0) is returned for complex nan inputs.
- ///
- /// Notes
- ///
- /// There is more than one definition of sign in common use for complex
- /// numbers.
- /// The definition used here is equivalent to
- /// which is different from a common alternative, .
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The sign of x.
- ///
- /// This is a scalar if x is a scalar.
- ///
- public NDarray sign(NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("sign", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Compute the Heaviside step function.
- ///
- /// The Heaviside step function is defined as:
- ///
- /// where x2 is often taken to be 0.5, but 0 and 1 are also sometimes used.
- ///
- /// Notes
- ///
- /// References
- ///
- ///
- /// The value of the function when x1 is 0.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The output array, element-wise Heaviside step function of x1.
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray heaviside(NDarray x2, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x2,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("heaviside", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Element-wise maximum of array elements.
- ///
- /// Compare two arrays and returns a new array containing the element-wise
- /// maxima.
- /// If one of the elements being compared is a NaN, then that
- /// element is returned.
- /// If both elements are NaNs then the first is
- /// returned.
- /// The latter distinction is important for complex NaNs, which
- /// are defined as at least one of the real or imaginary parts being a NaN.
- ///
- /// The net effect is that NaNs are propagated.
- ///
- /// Notes
- ///
- /// The maximum is equivalent to np.where(x1 >= x2, x1, x2) when
- /// neither x1 nor x2 are nans, but it is faster and does proper
- /// broadcasting.
- ///
- ///
- /// The arrays holding the elements to be compared.
- /// They must have
- /// the same shape, or shapes that can be broadcast to a single shape.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The maximum of x1 and x2, element-wise.
- ///
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray maximum(NDarray x1, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x1,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("maximum", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Element-wise minimum of array elements.
- ///
- /// Compare two arrays and returns a new array containing the element-wise
- /// minima.
- /// If one of the elements being compared is a NaN, then that
- /// element is returned.
- /// If both elements are NaNs then the first is
- /// returned.
- /// The latter distinction is important for complex NaNs, which
- /// are defined as at least one of the real or imaginary parts being a NaN.
- ///
- /// The net effect is that NaNs are propagated.
- ///
- /// Notes
- ///
- /// The minimum is equivalent to np.where(x1 <= x2, x1, x2) when
- /// neither x1 nor x2 are NaNs, but it is faster and does proper
- /// broadcasting.
- ///
- ///
- /// The arrays holding the elements to be compared.
- /// They must have
- /// the same shape, or shapes that can be broadcast to a single shape.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The minimum of x1 and x2, element-wise.
- ///
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray minimum(NDarray x1, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x1,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("minimum", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Element-wise maximum of array elements.
- ///
- /// Compare two arrays and returns a new array containing the element-wise
- /// maxima.
- /// If one of the elements being compared is a NaN, then the
- /// non-nan element is returned.
- /// If both elements are NaNs then the first
- /// is returned.
- /// The latter distinction is important for complex NaNs,
- /// which are defined as at least one of the real or imaginary parts being
- /// a NaN.
- /// The net effect is that NaNs are ignored when possible.
- ///
- /// Notes
- ///
- /// The fmax is equivalent to np.where(x1 >= x2, x1, x2) when neither
- /// x1 nor x2 are NaNs, but it is faster and does proper broadcasting.
- ///
- ///
- /// The arrays holding the elements to be compared.
- /// They must have
- /// the same shape.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The maximum of x1 and x2, element-wise.
- ///
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray fmax(NDarray x1, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x1,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("fmax", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Element-wise minimum of array elements.
- ///
- /// Compare two arrays and returns a new array containing the element-wise
- /// minima.
- /// If one of the elements being compared is a NaN, then the
- /// non-nan element is returned.
- /// If both elements are NaNs then the first
- /// is returned.
- /// The latter distinction is important for complex NaNs,
- /// which are defined as at least one of the real or imaginary parts being
- /// a NaN.
- /// The net effect is that NaNs are ignored when possible.
- ///
- /// Notes
- ///
- /// The fmin is equivalent to np.where(x1 <= x2, x1, x2) when neither
- /// x1 nor x2 are NaNs, but it is faster and does proper broadcasting.
- ///
- ///
- /// The arrays holding the elements to be compared.
- /// They must have
- /// the same shape.
- ///
- ///
- /// A location into which the result is stored.
- /// If provided, it must have
- /// a shape that the inputs broadcast to.
- /// If not provided or None,
- /// a freshly-allocated array is returned.
- /// A tuple (possible only as a
- /// keyword argument) must have length equal to the number of outputs.
- ///
- ///
- /// Values of True indicate to calculate the ufunc at that position, values
- /// of False indicate to leave the value in the output alone.
- ///
- ///
- /// The minimum of x1 and x2, element-wise.
- ///
- /// This is a scalar if both x1 and x2 are scalars.
- ///
- public NDarray fmin(NDarray x1, NDarray @out = null, NDarray @where = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- x1,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (@where!=null) kwargs["where"]=ToPython(@where);
- dynamic py = __self__.InvokeMethod("fmin", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Replace NaN with zero and infinity with large finite numbers.
- ///
- /// If x is inexact, NaN is replaced by zero, and infinity and -infinity
- /// replaced by the respectively largest and most negative finite floating
- /// point values representable by x.dtype.
- ///
- /// For complex dtypes, the above is applied to each of the real and
- /// imaginary components of x separately.
- ///
- /// If x is not inexact, then no replacements are made.
- ///
- /// Notes
- ///
- /// NumPy uses the IEEE Standard for Binary Floating-Point for Arithmetic
- /// (IEEE 754).
- /// This means that Not a Number is not equivalent to infinity.
- ///
- ///
- /// Whether to create a copy of x (True) or to replace values
- /// in-place (False).
- /// The in-place operation only occurs if
- /// casting to an array does not require a copy.
- ///
- /// Default is True.
- ///
- ///
- /// x, with the non-finite values replaced.
- /// If copy is False, this may
- /// be x itself.
- ///
- public NDarray nan_to_num(bool? copy = true)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (copy!=true) kwargs["copy"]=ToPython(copy);
- dynamic py = __self__.InvokeMethod("nan_to_num", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// If complex input returns a real array if complex parts are close to zero.
- ///
- /// “Close to zero” is defined as tol * (machine epsilon of the type for
- /// a).
- ///
- /// Notes
- ///
- /// Machine epsilon varies from machine to machine and between data types
- /// but Python floats on most platforms have a machine epsilon equal to
- /// 2.2204460492503131e-16. You can use ‘np.finfo(float).eps’ to print
- /// out the machine epsilon for floats.
- ///
- ///
- /// Tolerance in machine epsilons for the complex part of the elements
- /// in the array.
- ///
- ///
- /// If a is real, the type of a is used for the output.
- /// If a
- /// has complex elements, the returned type is float.
- ///
- public NDarray real_if_close(float tol = 100)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (tol!=100) kwargs["tol"]=ToPython(tol);
- dynamic py = __self__.InvokeMethod("real_if_close", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- /*
- ///
- /// One-dimensional linear interpolation.
- ///
- /// Returns the one-dimensional piecewise linear interpolant to a function
- /// with given discrete data points (xp, fp), evaluated at x.
- ///
- /// Notes
- ///
- /// Does not check that the x-coordinate sequence xp is increasing.
- ///
- /// If xp is not increasing, the results are nonsense.
- ///
- /// A simple check for increasing is:
- ///
- ///
- /// The x-coordinates of the data points, must be increasing if argument
- /// period is not specified.
- /// Otherwise, xp is internally sorted after
- /// normalizing the periodic boundaries with xp = xp % period.
- ///
- ///
- /// The y-coordinates of the data points, same length as xp.
- ///
- ///
- /// Value to return for x < xp[0], default is fp[0].
- ///
- ///
- /// Value to return for x > xp[-1], default is fp[-1].
- ///
- ///
- /// A period for the x-coordinates.
- /// This parameter allows the proper
- /// interpolation of angular x-coordinates.
- /// Parameters left and right
- /// are ignored if period is specified.
- ///
- ///
- /// The interpolated values, same shape as x.
- ///
- public float or complex (corresponding to fp) or ndarray interp(1-D sequence of floats xp, 1-D sequence of float or complex fp, optional float or complex corresponding to fp left = null, optional float or complex corresponding to fp right = null, None or float period = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- xp,
- fp,
- });
- var kwargs=new PyDict();
- if (left!=null) kwargs["left"]=ToPython(left);
- if (right!=null) kwargs["right"]=ToPython(right);
- if (period!=null) kwargs["period"]=ToPython(period);
- dynamic py = __self__.InvokeMethod("interp", pyargs, kwargs);
- return ToCsharp(py);
- }
- */
-
- ///
- /// Pads an array.
- ///
- /// Notes
- ///
- /// For an array with rank greater than 1, some of the padding of later
- /// axes is calculated from padding of previous axes.
- /// This is easiest to
- /// think about with a rank 2 array where the corners of the padded array
- /// are calculated by using padded values from the first axis.
- ///
- /// The padding function, if used, should return a rank 1 array equal in
- /// length to the vector argument with padded values replaced.
- /// It has the
- /// following signature:
- ///
- /// where
- ///
- ///
- /// Number of values padded to the edges of each axis.
- ///
- /// ((before_1, after_1), … (before_N, after_N)) unique pad widths
- /// for each axis.
- ///
- /// ((before, after),) yields same before and after pad for each axis.
- ///
- /// (pad,) or int is a shortcut for before = after = pad width for all
- /// axes.
- ///
- ///
- /// One of the following string values or a user supplied function.
- ///
- ///
- /// Used in ‘maximum’, ‘mean’, ‘median’, and ‘minimum’. Number of
- /// values at edge of each axis used to calculate the statistic value.
- ///
- /// ((before_1, after_1), … (before_N, after_N)) unique statistic
- /// lengths for each axis.
- ///
- /// ((before, after),) yields same before and after statistic lengths
- /// for each axis.
- ///
- /// (stat_length,) or int is a shortcut for before = after = statistic
- /// length for all axes.
- ///
- /// Default is None, to use the entire axis.
- ///
- ///
- /// Used in ‘constant’. The values to set the padded values for each
- /// axis.
- ///
- /// ((before_1, after_1), … (before_N, after_N)) unique pad constants
- /// for each axis.
- ///
- /// ((before, after),) yields same before and after constants for each
- /// axis.
- ///
- /// (constant,) or int is a shortcut for before = after = constant for
- /// all axes.
- ///
- /// Default is 0.
- ///
- ///
- /// Used in ‘linear_ramp’. The values used for the ending value of the
- /// linear_ramp and that will form the edge of the padded array.
- ///
- /// ((before_1, after_1), … (before_N, after_N)) unique end values
- /// for each axis.
- ///
- /// ((before, after),) yields same before and after end values for each
- /// axis.
- ///
- /// (constant,) or int is a shortcut for before = after = end value for
- /// all axes.
- ///
- /// Default is 0.
- ///
- ///
- /// Used in ‘reflect’, and ‘symmetric’. The ‘even’ style is the
- /// default with an unaltered reflection around the edge value.
- /// For
- /// the ‘odd’ style, the extended part of the array is created by
- /// subtracting the reflected values from two times the edge value.
- ///
- ///
- /// Padded array of rank equal to array with shape increased
- /// according to pad_width.
- ///
- public NDarray pad(NDarray pad_width, string mode, int[] stat_length = null, int[] constant_values = null, int[] end_values = null, string reflect_type = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- pad_width,
- mode,
- });
- var kwargs=new PyDict();
- if (stat_length!=null) kwargs["stat_length"]=ToPython(stat_length);
- if (constant_values!=null) kwargs["constant_values"]=ToPython(constant_values);
- if (end_values!=null) kwargs["end_values"]=ToPython(end_values);
- if (reflect_type!=null) kwargs["reflect_type"]=ToPython(reflect_type);
- dynamic py = __self__.InvokeMethod("pad", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Test whether each element of a 1-D array is also present in a second array.
- ///
- /// Returns a boolean array the same length as ar1 that is True
- /// where an element of ar1 is in ar2 and False otherwise.
- ///
- /// We recommend using isin instead of in1d for new code.
- ///
- /// Notes
- ///
- /// in1d can be considered as an element-wise function version of the
- /// python keyword in, for 1-D sequences.
- /// in1d(a, b) is roughly
- /// equivalent to np.array([item in b for item in a]).
- ///
- /// However, this idea fails if ar2 is a set, or similar (non-sequence)
- /// container: As ar2 is converted to an array, in those cases
- /// asarray(ar2) is an object array rather than the expected array of
- /// contained values.
- ///
- ///
- /// The values against which to test each value of ar1.
- ///
- ///
- /// If True, the input arrays are both assumed to be unique, which
- /// can speed up the calculation.
- /// Default is False.
- ///
- ///
- /// If True, the values in the returned array are inverted (that is,
- /// False where an element of ar1 is in ar2 and True otherwise).
- ///
- /// Default is False.
- /// np.in1d(a, b, invert=True) is equivalent
- /// to (but is faster than) np.invert(in1d(a, b)).
- ///
- ///
- /// The values ar1[in1d] are in ar2.
- ///
- public NDarray in1d(NDarray ar2, bool? assume_unique = false, bool? invert = false)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- ar2,
- });
- var kwargs=new PyDict();
- if (assume_unique!=false) kwargs["assume_unique"]=ToPython(assume_unique);
- if (invert!=false) kwargs["invert"]=ToPython(invert);
- dynamic py = __self__.InvokeMethod("in1d", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Find the intersection of two arrays.
- ///
- /// Return the sorted, unique values that are in both of the input arrays.
- ///
- ///
- /// Input arrays.
- /// Will be flattened if not already 1D.
- ///
- ///
- /// If True, the input arrays are both assumed to be unique, which
- /// can speed up the calculation.
- /// Default is False.
- ///
- ///
- /// If True, the indices which correspond to the intersection of the two
- /// arrays are returned.
- /// The first instance of a value is used if there are
- /// multiple.
- /// Default is False.
- ///
- ///
- /// A tuple of:
- /// intersect1d
- /// Sorted 1D array of common and unique elements.
- /// comm1
- /// The indices of the first occurrences of the common values in ar1.
- /// Only provided if return_indices is True.
- /// comm2
- /// The indices of the first occurrences of the common values in ar2.
- /// Only provided if return_indices is True.
- ///
- public (NDarray, NDarray, NDarray) intersect1d(NDarray ar1, bool assume_unique = false, bool return_indices = false)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- ar1,
- });
- var kwargs=new PyDict();
- if (assume_unique!=false) kwargs["assume_unique"]=ToPython(assume_unique);
- if (return_indices!=false) kwargs["return_indices"]=ToPython(return_indices);
- dynamic py = __self__.InvokeMethod("intersect1d", pyargs, kwargs);
- return (ToCsharp(py[0]), ToCsharp(py[1]), ToCsharp(py[2]));
- }
-
- ///
- /// Calculates element in test_elements, broadcasting over element only.
- ///
- /// Returns a boolean array of the same shape as element that is True
- /// where an element of element is in test_elements and False otherwise.
- ///
- /// Notes
- ///
- /// isin is an element-wise function version of the python keyword in.
- ///
- /// isin(a, b) is roughly equivalent to
- /// np.array([item in b for item in a]) if a and b are 1-D sequences.
- ///
- /// element and test_elements are converted to arrays if they are not
- /// already.
- /// If test_elements is a set (or other non-sequence collection)
- /// it will be converted to an object array with one element, rather than an
- /// array of the values contained in test_elements.
- /// This is a consequence
- /// of the array constructor’s way of handling non-sequence collections.
- ///
- /// Converting the set to a list usually gives the desired behavior.
- ///
- ///
- /// The values against which to test each value of element.
- ///
- /// This argument is flattened if it is an array or array_like.
- ///
- /// See notes for behavior with non-array-like parameters.
- ///
- ///
- /// If True, the input arrays are both assumed to be unique, which
- /// can speed up the calculation.
- /// Default is False.
- ///
- ///
- /// If True, the values in the returned array are inverted, as if
- /// calculating element not in test_elements.
- /// Default is False.
- ///
- /// np.isin(a, b, invert=True) is equivalent to (but faster
- /// than) np.invert(np.isin(a, b)).
- ///
- ///
- /// Has the same shape as element.
- /// The values element[isin]
- /// are in test_elements.
- ///
- public NDarray isin(NDarray test_elements, bool? assume_unique = false, bool? invert = false)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- test_elements,
- });
- var kwargs=new PyDict();
- if (assume_unique!=false) kwargs["assume_unique"]=ToPython(assume_unique);
- if (invert!=false) kwargs["invert"]=ToPython(invert);
- dynamic py = __self__.InvokeMethod("isin", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Find the set difference of two arrays.
- ///
- /// Return the unique values in ar1 that are not in ar2.
- ///
- ///
- /// Input comparison array.
- ///
- ///
- /// If True, the input arrays are both assumed to be unique, which
- /// can speed up the calculation.
- /// Default is False.
- ///
- ///
- /// 1D array of values in ar1 that are not in ar2. The result
- /// is sorted when assume_unique=False, but otherwise only sorted
- /// if the input is sorted.
- ///
- public NDarray setdiff1d(NDarray ar2, bool assume_unique = false)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- ar2,
- });
- var kwargs=new PyDict();
- if (assume_unique!=false) kwargs["assume_unique"]=ToPython(assume_unique);
- dynamic py = __self__.InvokeMethod("setdiff1d", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Find the set exclusive-or of two arrays.
- ///
- /// Return the sorted, unique values that are in only one (not both) of the
- /// input arrays.
- ///
- ///
- /// Input arrays.
- ///
- ///
- /// If True, the input arrays are both assumed to be unique, which
- /// can speed up the calculation.
- /// Default is False.
- ///
- ///
- /// Sorted 1D array of unique values that are in only one of the input
- /// arrays.
- ///
- public NDarray setxor1d(NDarray ar1, bool assume_unique = false)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- ar1,
- });
- var kwargs=new PyDict();
- if (assume_unique!=false) kwargs["assume_unique"]=ToPython(assume_unique);
- dynamic py = __self__.InvokeMethod("setxor1d", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Find the union of two arrays.
- ///
- /// Return the unique, sorted array of values that are in either of the two
- /// input arrays.
- ///
- ///
- /// Input arrays.
- /// They are flattened if they are not already 1D.
- ///
- ///
- /// Unique, sorted union of the input arrays.
- ///
- public NDarray union1d(NDarray ar1)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- ar1,
- });
- var kwargs=new PyDict();
- dynamic py = __self__.InvokeMethod("union1d", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return a sorted copy of an array.
- ///
- /// Notes
- ///
- /// The various sorting algorithms are characterized by their average speed,
- /// worst case performance, work space size, and whether they are stable.
- /// A
- /// stable sort keeps items with the same key in the same relative
- /// order.
- /// The three available algorithms have the following
- /// properties:
- ///
- /// All the sort algorithms make temporary copies of the data when
- /// sorting along any but the last axis.
- /// Consequently, sorting along
- /// the last axis is faster and uses less space than sorting along
- /// any other axis.
- ///
- /// The sort order for complex numbers is lexicographic.
- /// If both the real
- /// and imaginary parts are non-nan then the order is determined by the
- /// real parts except when they are equal, in which case the order is
- /// determined by the imaginary parts.
- ///
- /// Previous to numpy 1.4.0 sorting real and complex arrays containing nan
- /// values led to undefined behaviour.
- /// In numpy versions >= 1.4.0 nan
- /// values are sorted to the end.
- /// The extended sort order is:
- ///
- /// where R is a non-nan real value.
- /// Complex values with the same nan
- /// placements are sorted according to the non-nan part if it exists.
- ///
- /// Non-nan values are sorted as before.
- ///
- /// quicksort has been changed to an introsort which will switch
- /// heapsort when it does not make enough progress.
- /// This makes its
- /// worst case O(n*log(n)).
- ///
- /// ‘stable’ automatically choses the best stable sorting algorithm
- /// for the data type being sorted.
- /// It is currently mapped to
- /// merge sort.
- ///
- ///
- /// Axis along which to sort.
- /// If None, the array is flattened before
- /// sorting.
- /// The default is -1, which sorts along the last axis.
- ///
- ///
- /// Sorting algorithm.
- /// Default is ‘quicksort’.
- ///
- ///
- /// When a is an array with fields defined, this argument specifies
- /// which fields to compare first, second, etc.
- /// A single field can
- /// be specified as a string, and not all fields need be specified,
- /// but unspecified fields will still be used, in the order in which
- /// they come up in the dtype, to break ties.
- ///
- ///
- /// Array of the same type and shape as a.
- ///
- public NDarray sort(int? axis = -1, string kind = "quicksort", string order = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axis!=-1) kwargs["axis"]=ToPython(axis);
- if (kind!="quicksort") kwargs["kind"]=ToPython(kind);
- if (order!=null) kwargs["order"]=ToPython(order);
- dynamic py = __self__.InvokeMethod("sort", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Perform an indirect stable sort using a sequence of keys.
- ///
- /// Given multiple sorting keys, which can be interpreted as columns in a
- /// spreadsheet, lexsort returns an array of integer indices that describes
- /// the sort order by multiple columns.
- /// The last key in the sequence is used
- /// for the primary sort order, the second-to-last key for the secondary sort
- /// order, and so on.
- /// The keys argument must be a sequence of objects that
- /// can be converted to arrays of the same shape.
- /// If a 2D array is provided
- /// for the keys argument, it’s rows are interpreted as the sorting keys and
- /// sorting is according to the last row, second last row etc.
- ///
- ///
- /// Axis to be indirectly sorted.
- /// By default, sort over the last axis.
- ///
- ///
- /// Array of indices that sort the keys along the specified axis.
- ///
- public NDarray lexsort(int? axis = -1)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axis!=-1) kwargs["axis"]=ToPython(axis);
- dynamic py = __self__.InvokeMethod("lexsort", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Returns the indices that would sort an array.
- ///
- /// Perform an indirect sort along the given axis using the algorithm specified
- /// by the kind keyword.
- /// It returns an array of indices of the same shape as
- /// a that index data along the given axis in sorted order.
- ///
- /// Notes
- ///
- /// See sort for notes on the different sorting algorithms.
- ///
- /// As of NumPy 1.4.0 argsort works with real/complex arrays containing
- /// nan values.
- /// The enhanced sort order is documented in sort.
- ///
- ///
- /// Axis along which to sort.
- /// The default is -1 (the last axis).
- /// If None,
- /// the flattened array is used.
- ///
- ///
- /// Sorting algorithm.
- ///
- ///
- /// When a is an array with fields defined, this argument specifies
- /// which fields to compare first, second, etc.
- /// A single field can
- /// be specified as a string, and not all fields need be specified,
- /// but unspecified fields will still be used, in the order in which
- /// they come up in the dtype, to break ties.
- ///
- ///
- /// Array of indices that sort a along the specified axis.
- ///
- /// If a is one-dimensional, a[index_array] yields a sorted a.
- ///
- /// More generally, np.take_along_axis(a, index_array, axis=a) always
- /// yields the sorted a, irrespective of dimensionality.
- ///
- public NDarray argsort(int? axis = -1, string kind = "quicksort", string order = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axis!=-1) kwargs["axis"]=ToPython(axis);
- if (kind!="quicksort") kwargs["kind"]=ToPython(kind);
- if (order!=null) kwargs["order"]=ToPython(order);
- dynamic py = __self__.InvokeMethod("argsort", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return a copy of an array sorted along the first axis.
- ///
- /// Notes
- ///
- /// np.msort(a) is equivalent to np.sort(a, axis=0).
- ///
- ///
- /// Array of the same type and shape as a.
- ///
- public NDarray msort()
- {
- //auto-generated code, do not change
- var __self__=self;
- dynamic py = __self__.InvokeMethod("msort");
- return ToCsharp(py);
- }
-
- ///
- /// Sort a complex array using the real part first, then the imaginary part.
- ///
- ///
- /// Always returns a sorted complex array.
- ///
- public NDarray sort_complex()
- {
- //auto-generated code, do not change
- var __self__=self;
- dynamic py = __self__.InvokeMethod("sort_complex");
- return ToCsharp(py);
- }
-
- ///
- /// Return a partitioned copy of an array.
- ///
- /// Creates a copy of the array with its elements rearranged in such a
- /// way that the value of the element in k-th position is in the
- /// position it would be in a sorted array.
- /// All elements smaller than
- /// the k-th element are moved before this element and all equal or
- /// greater are moved behind it.
- /// The ordering of the elements in the two
- /// partitions is undefined.
- ///
- /// Notes
- ///
- /// The various selection algorithms are characterized by their average
- /// speed, worst case performance, work space size, and whether they are
- /// stable.
- /// A stable sort keeps items with the same key in the same
- /// relative order.
- /// The available algorithms have the following
- /// properties:
- ///
- /// All the partition algorithms make temporary copies of the data when
- /// partitioning along any but the last axis.
- /// Consequently,
- /// partitioning along the last axis is faster and uses less space than
- /// partitioning along any other axis.
- ///
- /// The sort order for complex numbers is lexicographic.
- /// If both the
- /// real and imaginary parts are non-nan then the order is determined by
- /// the real parts except when they are equal, in which case the order
- /// is determined by the imaginary parts.
- ///
- ///
- /// Element index to partition by.
- /// The k-th value of the element
- /// will be in its final sorted position and all smaller elements
- /// will be moved before it and all equal or greater elements behind
- /// it.
- /// The order of all elements in the partitions is undefined.
- /// If
- /// provided with a sequence of k-th it will partition all elements
- /// indexed by k-th of them into their sorted position at once.
- ///
- ///
- /// Axis along which to sort.
- /// If None, the array is flattened before
- /// sorting.
- /// The default is -1, which sorts along the last axis.
- ///
- ///
- /// Selection algorithm.
- /// Default is ‘introselect’.
- ///
- ///
- /// When a is an array with fields defined, this argument
- /// specifies which fields to compare first, second, etc.
- /// A single
- /// field can be specified as a string.
- /// Not all fields need be
- /// specified, but unspecified fields will still be used, in the
- /// order in which they come up in the dtype, to break ties.
- ///
- ///
- /// Array of the same type and shape as a.
- ///
- public NDarray partition(int[] kth, int? axis = -1, string kind = "introselect", string order = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- kth,
- });
- var kwargs=new PyDict();
- if (axis!=-1) kwargs["axis"]=ToPython(axis);
- if (kind!="introselect") kwargs["kind"]=ToPython(kind);
- if (order!=null) kwargs["order"]=ToPython(order);
- dynamic py = __self__.InvokeMethod("partition", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Perform an indirect partition along the given axis using the
- /// algorithm specified by the kind keyword.
- /// It returns an array of
- /// indices of the same shape as a that index data along the given
- /// axis in partitioned order.
- ///
- /// Notes
- ///
- /// See partition for notes on the different selection algorithms.
- ///
- ///
- /// Element index to partition by.
- /// The k-th element will be in its
- /// final sorted position and all smaller elements will be moved
- /// before it and all larger elements behind it.
- /// The order all
- /// elements in the partitions is undefined.
- /// If provided with a
- /// sequence of k-th it will partition all of them into their sorted
- /// position at once.
- ///
- ///
- /// Axis along which to sort.
- /// The default is -1 (the last axis).
- /// If
- /// None, the flattened array is used.
- ///
- ///
- /// Selection algorithm.
- /// Default is ‘introselect’
- ///
- ///
- /// When a is an array with fields defined, this argument
- /// specifies which fields to compare first, second, etc.
- /// A single
- /// field can be specified as a string, and not all fields need be
- /// specified, but unspecified fields will still be used, in the
- /// order in which they come up in the dtype, to break ties.
- ///
- ///
- /// Array of indices that partition a along the specified axis.
- ///
- /// If a is one-dimensional, a[index_array] yields a partitioned a.
- ///
- /// More generally, np.take_along_axis(a, index_array, axis=a) always
- /// yields the partitioned a, irrespective of dimensionality.
- ///
- public NDarray argpartition(int[] kth, int? axis = -1, string kind = "introselect", string order = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- kth,
- });
- var kwargs=new PyDict();
- if (axis!=-1) kwargs["axis"]=ToPython(axis);
- if (kind!="introselect") kwargs["kind"]=ToPython(kind);
- if (order!=null) kwargs["order"]=ToPython(order);
- dynamic py = __self__.InvokeMethod("argpartition", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Returns the indices of the maximum values along an axis.
- ///
- /// Notes
- ///
- /// In case of multiple occurrences of the maximum values, the indices
- /// corresponding to the first occurrence are returned.
- ///
- ///
- /// By default, the index is into the flattened array, otherwise
- /// along the specified axis.
- ///
- ///
- /// If provided, the result will be inserted into this array.
- /// It should
- /// be of the appropriate shape and dtype.
- ///
- ///
- /// Array of indices into the array.
- /// It has the same shape as a.shape
- /// with the dimension along axis removed.
- ///
- public NDarray argmax(int? axis = null, NDarray @out = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- if (@out!=null) kwargs["out"]=ToPython(@out);
- dynamic py = __self__.InvokeMethod("argmax", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the indices of the maximum values in the specified axis ignoring
- /// NaNs.
- /// For all-NaN slices ValueError is raised.
- /// Warning: the
- /// results cannot be trusted if a slice contains only NaNs and -Infs.
- ///
- ///
- /// Axis along which to operate.
- /// By default flattened input is used.
- ///
- ///
- /// An array of indices or a single index value.
- ///
- public NDarray nanargmax(int? axis = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- dynamic py = __self__.InvokeMethod("nanargmax", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Returns the indices of the minimum values along an axis.
- ///
- /// Notes
- ///
- /// In case of multiple occurrences of the minimum values, the indices
- /// corresponding to the first occurrence are returned.
- ///
- ///
- /// By default, the index is into the flattened array, otherwise
- /// along the specified axis.
- ///
- ///
- /// If provided, the result will be inserted into this array.
- /// It should
- /// be of the appropriate shape and dtype.
- ///
- ///
- /// Array of indices into the array.
- /// It has the same shape as a.shape
- /// with the dimension along axis removed.
- ///
- public NDarray argmin(int? axis = null, NDarray @out = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- if (@out!=null) kwargs["out"]=ToPython(@out);
- dynamic py = __self__.InvokeMethod("argmin", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the indices of the minimum values in the specified axis ignoring
- /// NaNs.
- /// For all-NaN slices ValueError is raised.
- /// Warning: the results
- /// cannot be trusted if a slice contains only NaNs and Infs.
- ///
- ///
- /// Axis along which to operate.
- /// By default flattened input is used.
- ///
- ///
- /// An array of indices or a single index value.
- ///
- public NDarray nanargmin(int? axis = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- dynamic py = __self__.InvokeMethod("nanargmin", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Find the indices of array elements that are non-zero, grouped by element.
- ///
- /// Notes
- ///
- /// np.argwhere(a) is the same as np.transpose(np.nonzero(a)).
- ///
- /// The output of argwhere is not suitable for indexing arrays.
- ///
- /// For this purpose use nonzero(a) instead.
- ///
- ///
- /// Indices of elements that are non-zero.
- /// Indices are grouped by element.
- ///
- public NDarray argwhere()
- {
- //auto-generated code, do not change
- var __self__=self;
- dynamic py = __self__.InvokeMethod("argwhere");
- return ToCsharp(py);
- }
-
- ///
- /// Return indices that are non-zero in the flattened version of a.
- ///
- /// This is equivalent to np.nonzero(np.ravel(a))[0].
- ///
- ///
- /// Output array, containing the indices of the elements of a.ravel()
- /// that are non-zero.
- ///
- public NDarray flatnonzero()
- {
- //auto-generated code, do not change
- var __self__=self;
- dynamic py = __self__.InvokeMethod("flatnonzero");
- return ToCsharp(py);
- }
-
- ///
- /// Find indices where elements should be inserted to maintain order.
- ///
- /// Find the indices into a sorted array a such that, if the
- /// corresponding elements in v were inserted before the indices, the
- /// order of a would be preserved.
- ///
- /// Assuming that a is sorted:
- ///
- /// Notes
- ///
- /// Binary search is used to find the required insertion points.
- ///
- /// As of NumPy 1.4.0 searchsorted works with real/complex arrays containing
- /// nan values.
- /// The enhanced sort order is documented in sort.
- ///
- /// This function is a faster version of the builtin python bisect.bisect_left
- /// (side='left') and bisect.bisect_right (side='right') functions,
- /// which is also vectorized in the v argument.
- ///
- ///
- /// Values to insert into a.
- ///
- ///
- /// If ‘left’, the index of the first suitable location found is given.
- ///
- /// If ‘right’, return the last such index.
- /// If there is no suitable
- /// index, return either 0 or N (where N is the length of a).
- ///
- ///
- /// Optional array of integer indices that sort array a into ascending
- /// order.
- /// They are typically the result of argsort.
- ///
- ///
- /// Array of insertion points with the same shape as v.
- ///
- public NDarray searchsorted(NDarray v, string side = "left", NDarray sorter = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- v,
- });
- var kwargs=new PyDict();
- if (side!="left") kwargs["side"]=ToPython(side);
- if (sorter!=null) kwargs["sorter"]=ToPython(sorter);
- dynamic py = __self__.InvokeMethod("searchsorted", pyargs, kwargs);
- return ToCsharp>(py);
- }
-
- ///
- /// Return the elements of an array that satisfy some condition.
- ///
- /// This is equivalent to np.compress(ravel(condition), ravel(arr)).
- /// If
- /// condition is boolean np.extract is equivalent to arr[condition].
- ///
- /// Note that place does the exact opposite of extract.
- ///
- ///
- /// Input array of the same size as condition.
- ///
- ///
- /// Rank 1 array of values from arr where condition is True.
- ///
- public NDarray extract(NDarray arr)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- arr,
- });
- var kwargs=new PyDict();
- dynamic py = __self__.InvokeMethod("extract", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Counts the number of non-zero values in the array a.
- ///
- /// The word “non-zero” is in reference to the Python 2.x
- /// built-in method __nonzero__() (renamed __bool__()
- /// in Python 3.x) of Python objects that tests an object’s
- /// “truthfulness”. For example, any number is considered
- /// truthful if it is nonzero, whereas any string is considered
- /// truthful if it is not the empty string.
- /// Thus, this function
- /// (recursively) counts how many elements in a (and in
- /// sub-arrays thereof) have their __nonzero__() or __bool__()
- /// method evaluated to True.
- ///
- ///
- /// Axis or tuple of axes along which to count non-zeros.
- ///
- /// Default is None, meaning that non-zeros will be counted
- /// along a flattened version of a.
- ///
- ///
- /// Number of non-zero values in the array along a given axis.
- ///
- /// Otherwise, the total number of non-zero values in the array
- /// is returned.
- ///
- public NDarray count_nonzero(Axis axis)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- dynamic py = __self__.InvokeMethod("count_nonzero", pyargs, kwargs);
- return ToCsharp>(py);
- }
-
- ///
- /// Counts the number of non-zero values in the array a.
- ///
- /// The word “non-zero” is in reference to the Python 2.x
- /// built-in method __nonzero__() (renamed __bool__()
- /// in Python 3.x) of Python objects that tests an object’s
- /// “truthfulness”. For example, any number is considered
- /// truthful if it is nonzero, whereas any string is considered
- /// truthful if it is not the empty string.
- /// Thus, this function
- /// (recursively) counts how many elements in a (and in
- /// sub-arrays thereof) have their __nonzero__() or __bool__()
- /// method evaluated to True.
- ///
- ///
- /// Number of non-zero values in the array along a given axis.
- ///
- /// Otherwise, the total number of non-zero values in the array
- /// is returned.
- ///
- public int count_nonzero()
- {
- //auto-generated code, do not change
- var __self__=self;
- dynamic py = __self__.InvokeMethod("count_nonzero");
- return ToCsharp(py);
- }
-
- ///
- /// Return minimum of an array or minimum along an axis, ignoring any NaNs.
- ///
- /// When all-NaN slices are encountered a RuntimeWarning is raised and
- /// Nan is returned for that slice.
- ///
- /// Notes
- ///
- /// NumPy uses the IEEE Standard for Binary Floating-Point for Arithmetic
- /// (IEEE 754).
- /// This means that Not a Number is not equivalent to infinity.
- ///
- /// Positive infinity is treated as a very large number and negative
- /// infinity is treated as a very small (i.e.
- /// negative) number.
- ///
- /// If the input has a integer type the function is equivalent to np.min.
- ///
- ///
- /// Axis or axes along which the minimum is computed.
- /// The default is to compute
- /// the minimum of the flattened array.
- ///
- ///
- /// Alternate output array in which to place the result.
- /// The default
- /// is None; if provided, it must have the same shape as the
- /// expected output, but the type will be cast if necessary.
- /// See
- /// doc.ufuncs for details.
- ///
- ///
- /// If this is set to True, the axes which are reduced are left
- /// in the result as dimensions with size one.
- /// With this option,
- /// the result will broadcast correctly against the original a.
- ///
- /// If the value is anything but the default, then
- /// keepdims will be passed through to the min method
- /// of sub-classes of ndarray.
- /// If the sub-classes methods
- /// does not implement keepdims any exceptions will be raised.
- ///
- ///
- /// An array with the same shape as a, with the specified axis
- /// removed.
- /// If a is a 0-d array, or if axis is None, an ndarray
- /// scalar is returned.
- /// The same dtype as a is returned.
- ///
- public NDarray nanmin(Axis axis = null, NDarray @out = null, bool? keepdims = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (keepdims!=null) kwargs["keepdims"]=ToPython(keepdims);
- dynamic py = __self__.InvokeMethod("nanmin", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Return the maximum of an array or maximum along an axis, ignoring any
- /// NaNs.
- /// When all-NaN slices are encountered a RuntimeWarning is
- /// raised and NaN is returned for that slice.
- ///
- /// Notes
- ///
- /// NumPy uses the IEEE Standard for Binary Floating-Point for Arithmetic
- /// (IEEE 754).
- /// This means that Not a Number is not equivalent to infinity.
- ///
- /// Positive infinity is treated as a very large number and negative
- /// infinity is treated as a very small (i.e.
- /// negative) number.
- ///
- /// If the input has a integer type the function is equivalent to np.max.
- ///
- ///
- /// Axis or axes along which the maximum is computed.
- /// The default is to compute
- /// the maximum of the flattened array.
- ///
- ///
- /// Alternate output array in which to place the result.
- /// The default
- /// is None; if provided, it must have the same shape as the
- /// expected output, but the type will be cast if necessary.
- /// See
- /// doc.ufuncs for details.
- ///
- ///
- /// If this is set to True, the axes which are reduced are left
- /// in the result as dimensions with size one.
- /// With this option,
- /// the result will broadcast correctly against the original a.
- ///
- /// If the value is anything but the default, then
- /// keepdims will be passed through to the max method
- /// of sub-classes of ndarray.
- /// If the sub-classes methods
- /// does not implement keepdims any exceptions will be raised.
- ///
- ///
- /// An array with the same shape as a, with the specified axis removed.
- ///
- /// If a is a 0-d array, or if axis is None, an ndarray scalar is
- /// returned.
- /// The same dtype as a is returned.
- ///
- public NDarray nanmax(Axis axis = null, NDarray @out = null, bool? keepdims = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (keepdims!=null) kwargs["keepdims"]=ToPython(keepdims);
- dynamic py = __self__.InvokeMethod("nanmax", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Range of values (maximum - minimum) along an axis.
- ///
- /// The name of the function comes from the acronym for ‘peak to peak’.
- ///
- ///
- /// Axis along which to find the peaks.
- /// By default, flatten the
- /// array.
- /// axis may be negative, in
- /// which case it counts from the last to the first axis.
- ///
- /// If this is a tuple of ints, a reduction is performed on multiple
- /// axes, instead of a single axis or all the axes as before.
- ///
- ///
- /// Alternative output array in which to place the result.
- /// It must
- /// have the same shape and buffer length as the expected output,
- /// but the type of the output values will be cast if necessary.
- ///
- ///
- /// If this is set to True, the axes which are reduced are left
- /// in the result as dimensions with size one.
- /// With this option,
- /// the result will broadcast correctly against the input array.
- ///
- /// If the default value is passed, then keepdims will not be
- /// passed through to the ptp method of sub-classes of
- /// ndarray, however any non-default value will be.
- /// If the
- /// sub-class’ method does not implement keepdims any
- /// exceptions will be raised.
- ///
- ///
- /// A new array holding the result, unless out was
- /// specified, in which case a reference to out is returned.
- ///
- public NDarray ptp(Axis axis = null, NDarray @out = null, bool? keepdims = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (keepdims!=null) kwargs["keepdims"]=ToPython(keepdims);
- dynamic py = __self__.InvokeMethod("ptp", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Compute the q-th percentile of the data along the specified axis.
- ///
- /// Returns the q-th percentile(s) of the array elements.
- ///
- /// Notes
- ///
- /// Given a vector V of length N, the q-th percentile of
- /// V is the value q/100 of the way from the minimum to the
- /// maximum in a sorted copy of V.
- /// The values and distances of
- /// the two nearest neighbors as well as the interpolation parameter
- /// will determine the percentile if the normalized ranking does not
- /// match the location of q exactly.
- /// This function is the same as
- /// the median if q=50, the same as the minimum if q=0 and the
- /// same as the maximum if q=100.
- ///
- ///
- /// Percentile or sequence of percentiles to compute, which must be between
- /// 0 and 100 inclusive.
- ///
- ///
- /// Axis or axes along which the percentiles are computed.
- /// The
- /// default is to compute the percentile(s) along a flattened
- /// version of the array.
- ///
- ///
- /// Alternative output array in which to place the result.
- /// It must
- /// have the same shape and buffer length as the expected output,
- /// but the type (of the output) will be cast if necessary.
- ///
- ///
- /// If True, then allow the input array a to be modified by intermediate
- /// calculations, to save memory.
- /// In this case, the contents of the input
- /// a after this function completes is undefined.
- ///
- ///
- /// This optional parameter specifies the interpolation method to
- /// use when the desired percentile lies between two data points
- /// i < j:
- ///
- ///
- /// If this is set to True, the axes which are reduced are left in
- /// the result as dimensions with size one.
- /// With this option, the
- /// result will broadcast correctly against the original array a.
- ///
- ///
- /// If q is a single percentile and axis=None, then the result
- /// is a scalar.
- /// If multiple percentiles are given, first axis of
- /// the result corresponds to the percentiles.
- /// The other axes are
- /// the axes that remain after the reduction of a.
- /// If the input
- /// contains integers or floats smaller than float64, the output
- /// data-type is float64. Otherwise, the output data-type is the
- /// same as that of the input.
- /// If out is specified, that array is
- /// returned instead.
- ///
- public NDarray percentile(NDarray q, Axis axis, NDarray @out = null, bool? overwrite_input = false, string interpolation = "linear", bool? keepdims = false)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- q,
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (overwrite_input!=false) kwargs["overwrite_input"]=ToPython(overwrite_input);
- if (interpolation!="linear") kwargs["interpolation"]=ToPython(interpolation);
- if (keepdims!=false) kwargs["keepdims"]=ToPython(keepdims);
- dynamic py = __self__.InvokeMethod("percentile", pyargs, kwargs);
- return ToCsharp>(py);
- }
-
- ///
- /// Compute the q-th percentile of the data along the specified axis.
- ///
- /// Returns the q-th percentile(s) of the array elements.
- ///
- /// Notes
- ///
- /// Given a vector V of length N, the q-th percentile of
- /// V is the value q/100 of the way from the minimum to the
- /// maximum in a sorted copy of V.
- /// The values and distances of
- /// the two nearest neighbors as well as the interpolation parameter
- /// will determine the percentile if the normalized ranking does not
- /// match the location of q exactly.
- /// This function is the same as
- /// the median if q=50, the same as the minimum if q=0 and the
- /// same as the maximum if q=100.
- ///
- ///
- /// Percentile or sequence of percentiles to compute, which must be between
- /// 0 and 100 inclusive.
- ///
- ///
- /// Alternative output array in which to place the result.
- /// It must
- /// have the same shape and buffer length as the expected output,
- /// but the type (of the output) will be cast if necessary.
- ///
- ///
- /// If True, then allow the input array a to be modified by intermediate
- /// calculations, to save memory.
- /// In this case, the contents of the input
- /// a after this function completes is undefined.
- ///
- ///
- /// This optional parameter specifies the interpolation method to
- /// use when the desired percentile lies between two data points
- /// i < j:
- ///
- ///
- /// If q is a single percentile and axis=None, then the result
- /// is a scalar.
- /// If multiple percentiles are given, first axis of
- /// the result corresponds to the percentiles.
- /// The other axes are
- /// the axes that remain after the reduction of a.
- /// If the input
- /// contains integers or floats smaller than float64, the output
- /// data-type is float64. Otherwise, the output data-type is the
- /// same as that of the input.
- /// If out is specified, that array is
- /// returned instead.
- ///
- public double percentile(NDarray q, NDarray @out = null, bool? overwrite_input = false, string interpolation = "linear")
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- q,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (overwrite_input!=false) kwargs["overwrite_input"]=ToPython(overwrite_input);
- if (interpolation!="linear") kwargs["interpolation"]=ToPython(interpolation);
- dynamic py = __self__.InvokeMethod("percentile", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Compute the qth percentile of the data along the specified axis,
- /// while ignoring nan values.
- ///
- /// Returns the qth percentile(s) of the array elements.
- ///
- /// Notes
- ///
- /// Given a vector V of length N, the q-th percentile of
- /// V is the value q/100 of the way from the minimum to the
- /// maximum in a sorted copy of V.
- /// The values and distances of
- /// the two nearest neighbors as well as the interpolation parameter
- /// will determine the percentile if the normalized ranking does not
- /// match the location of q exactly.
- /// This function is the same as
- /// the median if q=50, the same as the minimum if q=0 and the
- /// same as the maximum if q=100.
- ///
- ///
- /// Percentile or sequence of percentiles to compute, which must be between
- /// 0 and 100 inclusive.
- ///
- ///
- /// Axis or axes along which the percentiles are computed.
- /// The
- /// default is to compute the percentile(s) along a flattened
- /// version of the array.
- ///
- ///
- /// Alternative output array in which to place the result.
- /// It must
- /// have the same shape and buffer length as the expected output,
- /// but the type (of the output) will be cast if necessary.
- ///
- ///
- /// If True, then allow the input array a to be modified by intermediate
- /// calculations, to save memory.
- /// In this case, the contents of the input
- /// a after this function completes is undefined.
- ///
- ///
- /// This optional parameter specifies the interpolation method to
- /// use when the desired percentile lies between two data points
- /// i < j:
- ///
- ///
- /// If this is set to True, the axes which are reduced are left in
- /// the result as dimensions with size one.
- /// With this option, the
- /// result will broadcast correctly against the original array a.
- ///
- /// If this is anything but the default value it will be passed
- /// through (in the special case of an empty array) to the
- /// mean function of the underlying array.
- /// If the array is
- /// a sub-class and mean does not have the kwarg keepdims this
- /// will raise a RuntimeError.
- ///
- ///
- /// If q is a single percentile and axis=None, then the result
- /// is a scalar.
- /// If multiple percentiles are given, first axis of
- /// the result corresponds to the percentiles.
- /// The other axes are
- /// the axes that remain after the reduction of a.
- /// If the input
- /// contains integers or floats smaller than float64, the output
- /// data-type is float64. Otherwise, the output data-type is the
- /// same as that of the input.
- /// If out is specified, that array is
- /// returned instead.
- ///
- public NDarray nanpercentile(NDarray q, Axis axis, NDarray @out = null, bool? overwrite_input = false, string interpolation = "linear", bool? keepdims = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- q,
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (overwrite_input!=false) kwargs["overwrite_input"]=ToPython(overwrite_input);
- if (interpolation!="linear") kwargs["interpolation"]=ToPython(interpolation);
- if (keepdims!=null) kwargs["keepdims"]=ToPython(keepdims);
- dynamic py = __self__.InvokeMethod("nanpercentile", pyargs, kwargs);
- return ToCsharp>(py);
- }
-
- ///
- /// Compute the qth percentile of the data along the specified axis,
- /// while ignoring nan values.
- ///
- /// Returns the qth percentile(s) of the array elements.
- ///
- /// Notes
- ///
- /// Given a vector V of length N, the q-th percentile of
- /// V is the value q/100 of the way from the minimum to the
- /// maximum in a sorted copy of V.
- /// The values and distances of
- /// the two nearest neighbors as well as the interpolation parameter
- /// will determine the percentile if the normalized ranking does not
- /// match the location of q exactly.
- /// This function is the same as
- /// the median if q=50, the same as the minimum if q=0 and the
- /// same as the maximum if q=100.
- ///
- ///
- /// Percentile or sequence of percentiles to compute, which must be between
- /// 0 and 100 inclusive.
- ///
- ///
- /// Alternative output array in which to place the result.
- /// It must
- /// have the same shape and buffer length as the expected output,
- /// but the type (of the output) will be cast if necessary.
- ///
- ///
- /// If True, then allow the input array a to be modified by intermediate
- /// calculations, to save memory.
- /// In this case, the contents of the input
- /// a after this function completes is undefined.
- ///
- ///
- /// This optional parameter specifies the interpolation method to
- /// use when the desired percentile lies between two data points
- /// i < j:
- ///
- ///
- /// If q is a single percentile and axis=None, then the result
- /// is a scalar.
- /// If multiple percentiles are given, first axis of
- /// the result corresponds to the percentiles.
- /// The other axes are
- /// the axes that remain after the reduction of a.
- /// If the input
- /// contains integers or floats smaller than float64, the output
- /// data-type is float64. Otherwise, the output data-type is the
- /// same as that of the input.
- /// If out is specified, that array is
- /// returned instead.
- ///
- public double nanpercentile(NDarray q, NDarray @out = null, bool? overwrite_input = false, string interpolation = "linear")
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- q,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (overwrite_input!=false) kwargs["overwrite_input"]=ToPython(overwrite_input);
- if (interpolation!="linear") kwargs["interpolation"]=ToPython(interpolation);
- dynamic py = __self__.InvokeMethod("nanpercentile", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Compute the q-th quantile of the data along the specified axis.
- ///
- /// ..versionadded:: 1.15.0
- ///
- /// Notes
- ///
- /// Given a vector V of length N, the q-th quantile of
- /// V is the value q of the way from the minimum to the
- /// maximum in a sorted copy of V.
- /// The values and distances of
- /// the two nearest neighbors as well as the interpolation parameter
- /// will determine the quantile if the normalized ranking does not
- /// match the location of q exactly.
- /// This function is the same as
- /// the median if q=0.5, the same as the minimum if q=0.0 and the
- /// same as the maximum if q=1.0.
- ///
- ///
- /// Quantile or sequence of quantiles to compute, which must be between
- /// 0 and 1 inclusive.
- ///
- ///
- /// Axis or axes along which the quantiles are computed.
- /// The
- /// default is to compute the quantile(s) along a flattened
- /// version of the array.
- ///
- ///
- /// Alternative output array in which to place the result.
- /// It must
- /// have the same shape and buffer length as the expected output,
- /// but the type (of the output) will be cast if necessary.
- ///
- ///
- /// If True, then allow the input array a to be modified by intermediate
- /// calculations, to save memory.
- /// In this case, the contents of the input
- /// a after this function completes is undefined.
- ///
- ///
- /// This optional parameter specifies the interpolation method to
- /// use when the desired quantile lies between two data points
- /// i < j:
- ///
- ///
- /// If this is set to True, the axes which are reduced are left in
- /// the result as dimensions with size one.
- /// With this option, the
- /// result will broadcast correctly against the original array a.
- ///
- ///
- /// If q is a single quantile and axis=None, then the result
- /// is a scalar.
- /// If multiple quantiles are given, first axis of
- /// the result corresponds to the quantiles.
- /// The other axes are
- /// the axes that remain after the reduction of a.
- /// If the input
- /// contains integers or floats smaller than float64, the output
- /// data-type is float64. Otherwise, the output data-type is the
- /// same as that of the input.
- /// If out is specified, that array is
- /// returned instead.
- ///
- public NDarray quantile(NDarray q, Axis axis, NDarray @out = null, bool? overwrite_input = false, string interpolation = "linear", bool? keepdims = false)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- q,
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (overwrite_input!=false) kwargs["overwrite_input"]=ToPython(overwrite_input);
- if (interpolation!="linear") kwargs["interpolation"]=ToPython(interpolation);
- if (keepdims!=false) kwargs["keepdims"]=ToPython(keepdims);
- dynamic py = __self__.InvokeMethod("quantile", pyargs, kwargs);
- return ToCsharp>(py);
- }
-
- ///
- /// Compute the q-th quantile of the data along the specified axis.
- ///
- /// ..versionadded:: 1.15.0
- ///
- /// Notes
- ///
- /// Given a vector V of length N, the q-th quantile of
- /// V is the value q of the way from the minimum to the
- /// maximum in a sorted copy of V.
- /// The values and distances of
- /// the two nearest neighbors as well as the interpolation parameter
- /// will determine the quantile if the normalized ranking does not
- /// match the location of q exactly.
- /// This function is the same as
- /// the median if q=0.5, the same as the minimum if q=0.0 and the
- /// same as the maximum if q=1.0.
- ///
- ///
- /// Quantile or sequence of quantiles to compute, which must be between
- /// 0 and 1 inclusive.
- ///
- ///
- /// Alternative output array in which to place the result.
- /// It must
- /// have the same shape and buffer length as the expected output,
- /// but the type (of the output) will be cast if necessary.
- ///
- ///
- /// If True, then allow the input array a to be modified by intermediate
- /// calculations, to save memory.
- /// In this case, the contents of the input
- /// a after this function completes is undefined.
- ///
- ///
- /// This optional parameter specifies the interpolation method to
- /// use when the desired quantile lies between two data points
- /// i < j:
- ///
- ///
- /// If q is a single quantile and axis=None, then the result
- /// is a scalar.
- /// If multiple quantiles are given, first axis of
- /// the result corresponds to the quantiles.
- /// The other axes are
- /// the axes that remain after the reduction of a.
- /// If the input
- /// contains integers or floats smaller than float64, the output
- /// data-type is float64. Otherwise, the output data-type is the
- /// same as that of the input.
- /// If out is specified, that array is
- /// returned instead.
- ///
- public double quantile(NDarray q, NDarray @out = null, bool? overwrite_input = false, string interpolation = "linear")
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- q,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (overwrite_input!=false) kwargs["overwrite_input"]=ToPython(overwrite_input);
- if (interpolation!="linear") kwargs["interpolation"]=ToPython(interpolation);
- dynamic py = __self__.InvokeMethod("quantile", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Compute the qth quantile of the data along the specified axis,
- /// while ignoring nan values.
- ///
- /// Returns the qth quantile(s) of the array elements.
- ///
- /// .. versionadded:: 1.15.0
- ///
- ///
- /// Quantile or sequence of quantiles to compute, which must be between
- /// 0 and 1 inclusive.
- ///
- ///
- /// Axis or axes along which the quantiles are computed.
- /// The
- /// default is to compute the quantile(s) along a flattened
- /// version of the array.
- ///
- ///
- /// Alternative output array in which to place the result.
- /// It must
- /// have the same shape and buffer length as the expected output,
- /// but the type (of the output) will be cast if necessary.
- ///
- ///
- /// If True, then allow the input array a to be modified by intermediate
- /// calculations, to save memory.
- /// In this case, the contents of the input
- /// a after this function completes is undefined.
- ///
- ///
- /// This optional parameter specifies the interpolation method to
- /// use when the desired quantile lies between two data points
- /// i < j:
- ///
- ///
- /// If this is set to True, the axes which are reduced are left in
- /// the result as dimensions with size one.
- /// With this option, the
- /// result will broadcast correctly against the original array a.
- ///
- /// If this is anything but the default value it will be passed
- /// through (in the special case of an empty array) to the
- /// mean function of the underlying array.
- /// If the array is
- /// a sub-class and mean does not have the kwarg keepdims this
- /// will raise a RuntimeError.
- ///
- ///
- /// If q is a single percentile and axis=None, then the result
- /// is a scalar.
- /// If multiple quantiles are given, first axis of
- /// the result corresponds to the quantiles.
- /// The other axes are
- /// the axes that remain after the reduction of a.
- /// If the input
- /// contains integers or floats smaller than float64, the output
- /// data-type is float64. Otherwise, the output data-type is the
- /// same as that of the input.
- /// If out is specified, that array is
- /// returned instead.
- ///
- public NDarray nanquantile(NDarray q, Axis axis, NDarray @out = null, bool? overwrite_input = false, string interpolation = "linear", bool? keepdims = null)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- q,
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (overwrite_input!=false) kwargs["overwrite_input"]=ToPython(overwrite_input);
- if (interpolation!="linear") kwargs["interpolation"]=ToPython(interpolation);
- if (keepdims!=null) kwargs["keepdims"]=ToPython(keepdims);
- dynamic py = __self__.InvokeMethod("nanquantile", pyargs, kwargs);
- return ToCsharp>(py);
- }
-
- ///
- /// Compute the qth quantile of the data along the specified axis,
- /// while ignoring nan values.
- ///
- /// Returns the qth quantile(s) of the array elements.
- ///
- /// .. versionadded:: 1.15.0
- ///
- ///
- /// Quantile or sequence of quantiles to compute, which must be between
- /// 0 and 1 inclusive.
- ///
- ///
- /// Alternative output array in which to place the result.
- /// It must
- /// have the same shape and buffer length as the expected output,
- /// but the type (of the output) will be cast if necessary.
- ///
- ///
- /// If True, then allow the input array a to be modified by intermediate
- /// calculations, to save memory.
- /// In this case, the contents of the input
- /// a after this function completes is undefined.
- ///
- ///
- /// This optional parameter specifies the interpolation method to
- /// use when the desired quantile lies between two data points
- /// i < j:
- ///
- ///
- /// If q is a single percentile and axis=None, then the result
- /// is a scalar.
- /// If multiple quantiles are given, first axis of
- /// the result corresponds to the quantiles.
- /// The other axes are
- /// the axes that remain after the reduction of a.
- /// If the input
- /// contains integers or floats smaller than float64, the output
- /// data-type is float64. Otherwise, the output data-type is the
- /// same as that of the input.
- /// If out is specified, that array is
- /// returned instead.
- ///
- public double nanquantile(NDarray q, NDarray @out = null, bool? overwrite_input = false, string interpolation = "linear")
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- q,
- });
- var kwargs=new PyDict();
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (overwrite_input!=false) kwargs["overwrite_input"]=ToPython(overwrite_input);
- if (interpolation!="linear") kwargs["interpolation"]=ToPython(interpolation);
- dynamic py = __self__.InvokeMethod("nanquantile", pyargs, kwargs);
- return ToCsharp(py);
- }
-
- ///
- /// Compute the median along the specified axis.
- ///
- /// Returns the median of the array elements.
- ///
- /// Notes
- ///
- /// Given a vector V of length N, the median of V is the
- /// middle value of a sorted copy of V, V_sorted - i
- /// e., V_sorted[(N-1)/2], when N is odd, and the average of the
- /// two middle values of V_sorted when N is even.
- ///
- ///
- /// Axis or axes along which the medians are computed.
- /// The default
- /// is to compute the median along a flattened version of the array.
- ///
- /// A sequence of axes is supported since version 1.9.0.
- ///
- ///
- /// Alternative output array in which to place the result.
- /// It must
- /// have the same shape and buffer length as the expected output,
- /// but the type (of the output) will be cast if necessary.
- ///
- ///
- /// If True, then allow use of memory of input array a for
- /// calculations.
- /// The input array will be modified by the call to
- /// median.
- /// This will save memory when you do not need to preserve
- /// the contents of the input array.
- /// Treat the input as undefined,
- /// but it will probably be fully or partially sorted.
- /// Default is
- /// False.
- /// If overwrite_input is True and a is not already an
- /// ndarray, an error will be raised.
- ///
- ///
- /// If this is set to True, the axes which are reduced are left
- /// in the result as dimensions with size one.
- /// With this option,
- /// the result will broadcast correctly against the original arr.
- ///
- ///
- /// A new array holding the result.
- /// If the input contains integers
- /// or floats smaller than float64, then the output data-type is
- /// np.float64. Otherwise, the data-type of the output is the
- /// same as that of the input.
- /// If out is specified, that array is
- /// returned instead.
- ///
- public NDarray median(Axis axis, NDarray @out = null, bool? overwrite_input = false, bool? keepdims = false)
- {
- //auto-generated code, do not change
- var __self__=self;
- var pyargs=ToTuple(new object[]
- {
- });
- var kwargs=new PyDict();
- if (axis!=null) kwargs["axis"]=ToPython(axis);
- if (@out!=null) kwargs["out"]=ToPython(@out);
- if (overwrite_input!=false) kwargs["overwrite_input"]=ToPython(overwrite_input);
- if (keepdims!=false) kwargs["keepdims"]=ToPython(keepdims);
- dynamic py = __self__.InvokeMethod("median", pyargs, kwargs);
- return ToCsharp>(py);
- }
-
- ///