List<T>.Sort List<T>.Sort List<T>.Sort List<T>.Sort Method

Definición

Ordena los elementos o una parte de los elementos de List<T> mediante la implementación de IComparer<T> especificada o predeterminada o un delegado de Comparison<T> proporcionado para comparar elementos de lista.Sorts the elements or a portion of the elements in the List<T> using either the specified or default IComparer<T> implementation or a provided Comparison<T> delegate to compare list elements.

Sobrecargas

Sort(Comparison<T>) Sort(Comparison<T>) Sort(Comparison<T>) Sort(Comparison<T>)

Ordena los elementos de toda la List<T> utilizando el Comparison<T> especificado.Sorts the elements in the entire List<T> using the specified Comparison<T>.

Sort(Int32, Int32, IComparer<T>) Sort(Int32, Int32, IComparer<T>) Sort(Int32, Int32, IComparer<T>) Sort(Int32, Int32, IComparer<T>)

Ordena los elementos en un intervalo de elementos de la matriz List<T> usando el comparador especificado.Sorts the elements in a range of elements in List<T> using the specified comparer.

Sort() Sort() Sort() Sort()

Ordena los elementos de todo el objeto List<T> utilizando el comparador predeterminado.Sorts the elements in the entire List<T> using the default comparer.

Sort(IComparer<T>) Sort(IComparer<T>) Sort(IComparer<T>) Sort(IComparer<T>)

Ordena los elementos en la List<T> completa usando el comparador especificado.Sorts the elements in the entire List<T> using the specified comparer.

Sort(Comparison<T>) Sort(Comparison<T>) Sort(Comparison<T>) Sort(Comparison<T>)

Ordena los elementos de toda la List<T> utilizando el Comparison<T> especificado.Sorts the elements in the entire List<T> using the specified Comparison<T>.

public:
 void Sort(Comparison<T> ^ comparison);
public void Sort (Comparison<T> comparison);
member this.Sort : Comparison<'T> -> unit
Public Sub Sort (comparison As Comparison(Of T))

Parámetros

comparison
Comparison<T> Comparison<T> Comparison<T> Comparison<T>

Comparison<T> que se va a utilizar al comparar elementos.The Comparison<T> to use when comparing elements.

Excepciones

La implementación de comparison ha producido un error durante la ordenación.The implementation of comparison caused an error during the sort. Por ejemplo, es posible que comparison no devuelva 0 al comparar un elemento consigo mismo.For example, comparison might not return 0 when comparing an item with itself.

Ejemplos

En el código siguiente se Sort muestran Sort las sobrecargas de los métodos y en un objeto comercial simple.The following code demonstrates the Sort and Sort method overloads on a simple business object. La llamada Sort al método provoca el uso del comparador predeterminado para el tipo de elemento y el Sort método se implementa mediante un método anónimo.Calling the Sort method results in the use of the default comparer for the Part type, and the Sort method is implemented using an anonymous method.

using System;
using System.Collections.Generic;
// Simple business object. A PartId is used to identify the type of part 
// but the part name can change. 
public class Part : IEquatable<Part> , IComparable<Part>
{
    public string PartName { get; set; }

    public int PartId { get; set; }

    public override string ToString()
    {
        return "ID: " + PartId + "   Name: " + PartName;
    }
    public override bool Equals(object obj)
    {
        if (obj == null) return false;
        Part objAsPart = obj as Part;
        if (objAsPart == null) return false;
        else return Equals(objAsPart);
    }
    public int SortByNameAscending(string name1, string name2)
    {
        
        return name1.CompareTo(name2);
    }

    // Default comparer for Part type.
    public int CompareTo(Part comparePart)
    {
          // A null value means that this object is greater.
        if (comparePart == null)
            return 1;
            
        else
            return this.PartId.CompareTo(comparePart.PartId);
    }
    public override int GetHashCode()
    {
        return PartId;
    }
    public bool Equals(Part other)
    {
        if (other == null) return false;
        return (this.PartId.Equals(other.PartId));
    }
    // Should also override == and != operators.

}
public class Example
{
    public static void Main()
    {
        // Create a list of parts.
        List<Part> parts = new List<Part>();

        // Add parts to the list.
        parts.Add(new Part() { PartName = "regular seat", PartId = 1434 });
        parts.Add(new Part() { PartName= "crank arm", PartId = 1234 });
        parts.Add(new Part() { PartName = "shift lever", PartId = 1634 }); ;
        // Name intentionally left null.
        parts.Add(new Part() {  PartId = 1334 });
        parts.Add(new Part() { PartName = "banana seat", PartId = 1444 });
        parts.Add(new Part() { PartName = "cassette", PartId = 1534 });
       

        // Write out the parts in the list. This will call the overridden 
        // ToString method in the Part class.
        Console.WriteLine("\nBefore sort:");
        foreach (Part aPart in parts)
        {
            Console.WriteLine(aPart);
        }


        // Call Sort on the list. This will use the 
        // default comparer, which is the Compare method 
        // implemented on Part.
        parts.Sort();


        Console.WriteLine("\nAfter sort by part number:");
        foreach (Part aPart in parts)
        {
            Console.WriteLine(aPart);
        }
       
        // This shows calling the Sort(Comparison(T) overload using 
        // an anonymous method for the Comparison delegate. 
        // This method treats null as the lesser of two values.
        parts.Sort(delegate(Part x, Part y)
        {
            if (x.PartName == null && y.PartName == null) return 0;
            else if (x.PartName == null) return -1;
            else if (y.PartName == null) return 1;
            else return x.PartName.CompareTo(y.PartName);
        });

        Console.WriteLine("\nAfter sort by name:");
        foreach (Part aPart in parts)
        {
            Console.WriteLine(aPart);
        }
       
        /*
       
            Before sort:
		ID: 1434   Name: regular seat
		ID: 1234   Name: crank arm
		ID: 1634   Name: shift lever
		ID: 1334   Name:
		ID: 1444   Name: banana seat
		ID: 1534   Name: cassette

	    After sort by part number:
		ID: 1234   Name: crank arm
		ID: 1334   Name:
		ID: 1434   Name: regular seat
		ID: 1444   Name: banana seat
		ID: 1534   Name: cassette
		ID: 1634   Name: shift lever

	    After sort by name:
		ID: 1334   Name:
		ID: 1444   Name: banana seat
		ID: 1534   Name: cassette
		ID: 1234   Name: crank arm
		ID: 1434   Name: regular seat
		ID: 1634   Name: shift lever

         */

    }
}
Imports System.Collections.Generic
' Simple business object. A PartId is used to identify the type of part 
' but the part name can change. 
Public Class Part
    Implements IEquatable(Of Part)
    Implements IComparable(Of Part)
    Public Property PartName() As String
        Get
            Return m_PartName
        End Get
        Set(value As String)
            m_PartName = Value
        End Set
    End Property
    Private m_PartName As String

    Public Property PartId() As Integer
        Get
            Return m_PartId
        End Get
        Set(value As Integer)
            m_PartId = Value
        End Set
    End Property
    Private m_PartId As Integer

    Public Overrides Function ToString() As String
        Return "ID: " & PartId & "   Name: " & PartName
    End Function

    Public Overrides Function Equals(obj As Object) As Boolean
        If obj Is Nothing Then
            Return False
        End If
        Dim objAsPart As Part = TryCast(obj, Part)
        If objAsPart Is Nothing Then
            Return False
        Else
            Return Equals(objAsPart)
        End If
    End Function

    Public Function SortByNameAscending(name1 As String, name2 As String) As Integer

        Return name1.CompareTo(name2)
    End Function

    ' Default comparer for Part.
    Public Function CompareTo(comparePart As Part) As Integer _
            Implements IComparable(Of ListSortVB.Part).CompareTo
        ' A null value means that this object is greater.
        If comparePart Is Nothing Then
            Return 1
        Else

            Return Me.PartId.CompareTo(comparePart.PartId)
        End If
    End Function
    Public Overrides Function GetHashCode() As Integer
        Return PartId
    End Function
    Public Overloads Function Equals(other As Part) As Boolean Implements IEquatable(Of ListSortVB.Part).Equals
        If other Is Nothing Then
            Return False
        End If
        Return (Me.PartId.Equals(other.PartId))
    End Function
    ' Should also override == and != operators.

End Class
Public Class Example
    Public Shared Sub Main()
        ' Create a list of parts.
        Dim parts As New List(Of Part)()

        ' Add parts to the list.
        parts.Add(New Part() With { _
             .PartName = "regular seat", _
             .PartId = 1434 _
        })
        parts.Add(New Part() With { _
             .PartName = "crank arm", _
             .PartId = 1234 _
        })
        parts.Add(New Part() With { _
             .PartName = "shift lever", _
             .PartId = 1634 _
        })


        ' Name intentionally left null.
        parts.Add(New Part() With { _
             .PartId = 1334 _
        })
        parts.Add(New Part() With { _
             .PartName = "banana seat", _
             .PartId = 1444 _
        })
        parts.Add(New Part() With { _
             .PartName = "cassette", _
             .PartId = 1534 _
        })


        ' Write out the parts in the list. This will call the overridden 
        ' ToString method in the Part class.
        Console.WriteLine(vbLf & "Before sort:")
        For Each aPart As Part In parts
            Console.WriteLine(aPart)
        Next


        ' Call Sort on the list. This will use the 
        ' default comparer, which is the Compare method 
        ' implemented on Part.
        parts.Sort()


        Console.WriteLine(vbLf & "After sort by part number:")
        For Each aPart As Part In parts
            Console.WriteLine(aPart)
        Next

        ' This shows calling the Sort(Comparison(T) overload using 
        ' an anonymous delegate method. 
        ' This method treats null as the lesser of two values.
        parts.Sort(Function(x As Part, y As Part)
                             If x.PartName Is Nothing AndAlso y.PartName Is Nothing Then
                                 Return 0
                             ElseIf x.PartName Is Nothing Then
                                 Return -1
                             ElseIf y.PartName Is Nothing Then
                                 Return 1
                             Else
                                 Return x.PartName.CompareTo(y.PartName)
                             End If
                         End Function)
        

        Console.WriteLine(vbLf & "After sort by name:")
        For Each aPart As Part In parts
            Console.WriteLine(aPart)
        Next

        '
        '        
        '            Before sort:
        '            ID: 1434   Name: regular seat
        '            ID: 1234   Name: crank arm
        '            ID: 1634   Name: shift lever
        '            ID: 1334   Name:
        '            ID: 1444   Name: banana seat
        '            ID: 1534   Name: cassette
        '
        '            After sort by part number:
        '            ID: 1234   Name: crank arm
        '            ID: 1334   Name:
        '            ID: 1434   Name: regular seat
        '            ID: 1444   Name: banana seat
        '            ID: 1534   Name: cassette
        '            ID: 1634   Name: shift lever
        '
        '            After sort by name:
        '            ID: 1334   Name:
        '            ID: 1444   Name: banana seat
        '            ID: 1534   Name: cassette
        '            ID: 1234   Name: crank arm
        '            ID: 1434   Name: regular seat
        '            ID: 1634   Name: shift lever

    End Sub
End Class

En el ejemplo siguiente se Sort(Comparison<T>) muestra la sobrecarga del método.The following example demonstrates the Sort(Comparison<T>) method overload.

En el ejemplo se define un método de comparación alternativo para CompareDinosByLengthlas cadenas, denominados.The example defines an alternative comparison method for strings, named CompareDinosByLength. Este método funciona de la siguiente manera: En primer lugar, se prueban nulllas comparaciones de y una referencia nula se trata como menor que un valor no NULL.This method works as follows: First, the comparands are tested for null, and a null reference is treated as less than a non-null. En segundo lugar, se comparan las longitudes de cadena y se considera que la cadena más larga es mayor.Second, the string lengths are compared, and the longer string is deemed to be greater. En tercer lugar, si las longitudes son iguales, se usa la comparación de cadenas ordinaria.Third, if the lengths are equal, ordinary string comparison is used.

Un List<T> de cadenas se crea y rellena con cuatro cadenas, en ningún orden determinado.A List<T> of strings is created and populated with four strings, in no particular order. La lista también incluye una cadena vacía y una referencia nula.The list also includes an empty string and a null reference. La lista se muestra, se ordena mediante un Comparison<T> delegado genérico que representa CompareDinosByLength el método y se muestra de nuevo.The list is displayed, sorted using a Comparison<T> generic delegate representing the CompareDinosByLength method, and displayed again.

using namespace System;
using namespace System::Collections::Generic;

int CompareDinosByLength(String^ x, String^ y)
{
    if (x == nullptr)
    {
        if (y == nullptr)
        {
            // If x is null and y is null, they're
            // equal. 
            return 0;
        }
        else
        {
            // If x is null and y is not null, y
            // is greater. 
            return -1;
        }
    }
    else
    {
        // If x is not null...
        //
        if (y == nullptr)
            // ...and y is null, x is greater.
        {
            return 1;
        }
        else
        {
            // ...and y is not null, compare the 
            // lengths of the two strings.
            //
            int retval = x->Length.CompareTo(y->Length);

            if (retval != 0)
            {
                // If the strings are not of equal length,
                // the longer string is greater.
                //
                return retval;
            }
            else
            {
                // If the strings are of equal length,
                // sort them with ordinary string comparison.
                //
                return x->CompareTo(y);
            }
        }
    }
};

void Display(List<String^>^ list)
{
    Console::WriteLine();
    for each(String^ s in list)
    {
        if (s == nullptr)
            Console::WriteLine("(null)");
        else
            Console::WriteLine("\"{0}\"", s);
    }
};

void main()
{
    List<String^>^ dinosaurs = gcnew List<String^>();
    dinosaurs->Add("Pachycephalosaurus");
    dinosaurs->Add("Amargasaurus");
    dinosaurs->Add("");
    dinosaurs->Add(nullptr);
    dinosaurs->Add("Mamenchisaurus");
    dinosaurs->Add("Deinonychus");
    Display(dinosaurs);

    Console::WriteLine("\nSort with generic Comparison<String^> delegate:");
    dinosaurs->Sort(
        gcnew Comparison<String^>(CompareDinosByLength));
    Display(dinosaurs);

}

/* This code example produces the following output:

"Pachycephalosaurus"
"Amargasaurus"
""
(null)
"Mamenchisaurus"
"Deinonychus"

Sort with generic Comparison<String^> delegate:

(null)
""
"Deinonychus"
"Amargasaurus"
"Mamenchisaurus"
"Pachycephalosaurus"
 */
using System;
using System.Collections.Generic;

public class Example
{
    private static int CompareDinosByLength(string x, string y)
    {
        if (x == null)
        {
            if (y == null)
            {
                // If x is null and y is null, they're
                // equal. 
                return 0;
            }
            else
            {
                // If x is null and y is not null, y
                // is greater. 
                return -1;
            }
        }
        else
        {
            // If x is not null...
            //
            if (y == null)
                // ...and y is null, x is greater.
            {
                return 1;
            }
            else
            {
                // ...and y is not null, compare the 
                // lengths of the two strings.
                //
                int retval = x.Length.CompareTo(y.Length);

                if (retval != 0)
                {
                    // If the strings are not of equal length,
                    // the longer string is greater.
                    //
                    return retval;
                }
                else
                {
                    // If the strings are of equal length,
                    // sort them with ordinary string comparison.
                    //
                    return x.CompareTo(y);
                }
            }
        }
    }

    public static void Main()
    {
        List<string> dinosaurs = new List<string>();
        dinosaurs.Add("Pachycephalosaurus");
        dinosaurs.Add("Amargasaurus");
        dinosaurs.Add("");
        dinosaurs.Add(null);
        dinosaurs.Add("Mamenchisaurus");
        dinosaurs.Add("Deinonychus");
        Display(dinosaurs);

        Console.WriteLine("\nSort with generic Comparison<string> delegate:");
        dinosaurs.Sort(CompareDinosByLength);
        Display(dinosaurs);

    }

    private static void Display(List<string> list)
    {
        Console.WriteLine();
        foreach( string s in list )
        {
            if (s == null)
                Console.WriteLine("(null)");
            else
                Console.WriteLine("\"{0}\"", s);
        }
    }
}

/* This code example produces the following output:

"Pachycephalosaurus"
"Amargasaurus"
""
(null)
"Mamenchisaurus"
"Deinonychus"

Sort with generic Comparison<string> delegate:

(null)
""
"Deinonychus"
"Amargasaurus"
"Mamenchisaurus"
"Pachycephalosaurus"
 */
Imports System
Imports System.Collections.Generic

Public Class Example

    Private Shared Function CompareDinosByLength( _
        ByVal x As String, ByVal y As String) As Integer

        If x Is Nothing Then
            If y Is Nothing Then 
                ' If x is Nothing and y is Nothing, they're
                ' equal. 
                Return 0
            Else
                ' If x is Nothing and y is not Nothing, y
                ' is greater. 
                Return -1
            End If
        Else
            ' If x is not Nothing...
            '
            If y Is Nothing Then
                ' ...and y is Nothing, x is greater.
                Return 1
            Else
                ' ...and y is not Nothing, compare the 
                ' lengths of the two strings.
                '
                Dim retval As Integer = _
                    x.Length.CompareTo(y.Length)

                If retval <> 0 Then 
                    ' If the strings are not of equal length,
                    ' the longer string is greater.
                    '
                    Return retval
                Else
                    ' If the strings are of equal length,
                    ' sort them with ordinary string comparison.
                    '
                    Return x.CompareTo(y)
                End If
            End If
        End If

    End Function

    Public Shared Sub Main()

        Dim dinosaurs As New List(Of String)
        dinosaurs.Add("Pachycephalosaurus")
        dinosaurs.Add("Amargasaurus")
        dinosaurs.Add("")
        dinosaurs.Add(Nothing)
        dinosaurs.Add("Mamenchisaurus")
        dinosaurs.Add("Deinonychus")
        Display(dinosaurs)

        Console.WriteLine(vbLf & "Sort with generic Comparison(Of String) delegate:")
        dinosaurs.Sort(AddressOf CompareDinosByLength)
        Display(dinosaurs)

    End Sub

    Private Shared Sub Display(ByVal lis As List(Of String))
        Console.WriteLine()
        For Each s As String In lis
            If s Is Nothing Then
                Console.WriteLine("(Nothing)")
            Else
                Console.WriteLine("""{0}""", s)
            End If
        Next
    End Sub
End Class

' This code example produces the following output:
'
'"Pachycephalosaurus"
'"Amargasaurus"
'""
'(Nothing)
'"Mamenchisaurus"
'"Deinonychus"
'
'Sort with generic Comparison(Of String) delegate:
'
'(Nothing)
'""
'"Deinonychus"
'"Amargasaurus"
'"Mamenchisaurus"
'"Pachycephalosaurus"

Comentarios

Si comparison se proporciona, los elementos List<T> de se ordenan utilizando el método representado por el delegado.If comparison is provided, the elements of the List<T> are sorted using the method represented by the delegate.

Si comparison ArgumentNullException es null, se produce una excepción.If comparison is null, an ArgumentNullException is thrown.

Este método usa Array.Sort, que aplica el orden introspectiva de la siguiente manera:This method uses Array.Sort, which applies the introspective sort as follows:

  • Si el tamaño de la partición es inferior a 16 elementos, usa un algoritmo de ordenación de inserción.If the partition size is fewer than 16 elements, it uses an insertion sort algorithm

  • Si el número de particiones supera 2 log n, donde n es el intervalo de la matriz de entrada, usa un algoritmo Heapsort .If the number of partitions exceeds 2 log n, where n is the range of the input array, it uses a Heapsort algorithm.

  • De lo contrario, usa un algoritmo Quicksort.Otherwise, it uses a Quicksort algorithm.

Esta implementación realiza una ordenación inestable; es decir, si dos elementos son iguales, es posible que no se conserve su orden.This implementation performs an unstable sort; that is, if two elements are equal, their order might not be preserved. Por el contrario, una ordenación estable conserva el orden de los elementos que son iguales.In contrast, a stable sort preserves the order of elements that are equal.

En promedio, este método es una operación o (n log n), donde n es Count; en el peor de los casos, es una operación o (n2).On average, this method is an O(n log n) operation, where n is Count; in the worst case it is an O(n2) operation.

Consulte también:

Sort(Int32, Int32, IComparer<T>) Sort(Int32, Int32, IComparer<T>) Sort(Int32, Int32, IComparer<T>) Sort(Int32, Int32, IComparer<T>)

Ordena los elementos en un intervalo de elementos de la matriz List<T> usando el comparador especificado.Sorts the elements in a range of elements in List<T> using the specified comparer.

public:
 void Sort(int index, int count, System::Collections::Generic::IComparer<T> ^ comparer);
public void Sort (int index, int count, System.Collections.Generic.IComparer<T> comparer);
member this.Sort : int * int * System.Collections.Generic.IComparer<'T> -> unit
Public Sub Sort (index As Integer, count As Integer, comparer As IComparer(Of T))

Parámetros

index
Int32 Int32 Int32 Int32

Índice inicial de base cero del intervalo que se va a ordenar.The zero-based starting index of the range to sort.

count
Int32 Int32 Int32 Int32

Longitud del intervalo que se va a ordenar.The length of the range to sort.

comparer
IComparer<T> IComparer<T> IComparer<T> IComparer<T>

Implementación de IComparer<T> que se va a utilizar al comparar elementos, o null para utilizar el comparador predeterminado Default.The IComparer<T> implementation to use when comparing elements, or null to use the default comparer Default.

Excepciones

index es menor que 0.index is less than 0.

o bien-or- count es menor que 0.count is less than 0.

index y count no especifican un intervalo válido en List<T>.index and count do not specify a valid range in the List<T>.

O bien-or- La implementación de comparer produjo un error durante la ordenación.The implementation of comparer caused an error during the sort. Por ejemplo, es posible que comparer no devuelva 0 al comparar un elemento consigo mismo.For example, comparer might not return 0 when comparing an item with itself.

comparer es null, y el comparador predeterminado Default no puede encontrar una implementación de la interfaz genérica IComparable<T> o la interfaz IComparable del tipo T.comparer is null, and the default comparer Default cannot find implementation of the IComparable<T> generic interface or the IComparable interface for type T.

Ejemplos

En el ejemplo siguiente se Sort(Int32, Int32, IComparer<T>) muestra la sobrecarga del BinarySearch(Int32, Int32, T, IComparer<T>) método y la sobrecarga del método.The following example demonstrates the Sort(Int32, Int32, IComparer<T>) method overload and the BinarySearch(Int32, Int32, T, IComparer<T>) method overload.

En el ejemplo se define un comparador alternativo para las cadenas denominadas DinoCompare IComparer<string> ,IComparer(Of String) que implementa la IComparer<String^> interfaz genérica C++(en Visual Basic, en visual).The example defines an alternative comparer for strings named DinoCompare, which implements the IComparer<string> (IComparer(Of String) in Visual Basic, IComparer<String^> in Visual C++) generic interface. El comparador funciona de la siguiente manera: En primer lugar, se prueban nulllas comparaciones de y una referencia nula se trata como menor que un valor no NULL.The comparer works as follows: First, the comparands are tested for null, and a null reference is treated as less than a non-null. En segundo lugar, se comparan las longitudes de cadena y se considera que la cadena más larga es mayor.Second, the string lengths are compared, and the longer string is deemed to be greater. En tercer lugar, si las longitudes son iguales, se usa la comparación de cadenas ordinaria.Third, if the lengths are equal, ordinary string comparison is used.

Un List<T> de cadenas se crea y rellena con los nombres de cinco dinosaurios herbivorous y tres dinosaurios de carnívoros.A List<T> of strings is created and populated with the names of five herbivorous dinosaurs and three carnivorous dinosaurs. Dentro de cada uno de los dos grupos, los nombres no se encuentran en ningún criterio de ordenación determinado.Within each of the two groups, the names are not in any particular sort order. Se muestra la lista, el intervalo de herbivores se ordena mediante el comparador alternativo y la lista se muestra de nuevo.The list is displayed, the range of herbivores is sorted using the alternate comparer, and the list is displayed again.

La BinarySearch(Int32, Int32, T, IComparer<T>) sobrecarga del método se usa para buscar solo el intervalo de herbivores para "Brachiosaurus".The BinarySearch(Int32, Int32, T, IComparer<T>) method overload is then used to search only the range of herbivores for "Brachiosaurus". No se encuentra la cadena y el complemento bit a bit (el operador ~ C# en y C++el Xor visual,-1 en Visual Basic) del número negativo devuelto BinarySearch(Int32, Int32, T, IComparer<T>) por el método se utiliza como índice para insertar la nueva cadena.The string is not found, and the bitwise complement (the ~ operator in C# and Visual C++, Xor -1 in Visual Basic) of the negative number returned by the BinarySearch(Int32, Int32, T, IComparer<T>) method is used as an index for inserting the new string.

using namespace System;
using namespace System::Collections::Generic;

public ref class DinoComparer: IComparer<String^>
{
public:
    virtual int Compare(String^ x, String^ y)
    {
        if (x == nullptr)
        {
            if (y == nullptr)
            {
                // If x is null and y is null, they're
                // equal. 
                return 0;
            }
            else
            {
                // If x is null and y is not null, y
                // is greater. 
                return -1;
            }
        }
        else
        {
            // If x is not null...
            //
            if (y == nullptr)
                // ...and y is null, x is greater.
            {
                return 1;
            }
            else
            {
                // ...and y is not null, compare the 
                // lengths of the two strings.
                //
                int retval = x->Length.CompareTo(y->Length);

                if (retval != 0)
                {
                    // If the strings are not of equal length,
                    // the longer string is greater.
                    //
                    return retval;
                }
                else
                {
                    // If the strings are of equal length,
                    // sort them with ordinary string comparison.
                    //
                    return x->CompareTo(y);
                }
            }
        }
    }
};

void Display(List<String^>^ list)
{
    Console::WriteLine();
    for each(String^ s in list)
    {
        Console::WriteLine(s);
    }
};

void main()
{
    List<String^>^ dinosaurs = gcnew List<String^>();

    dinosaurs->Add("Pachycephalosaurus");
    dinosaurs->Add("Parasauralophus");
    dinosaurs->Add("Amargasaurus");
    dinosaurs->Add("Galimimus");
    dinosaurs->Add("Mamenchisaurus");
    dinosaurs->Add("Deinonychus");
    dinosaurs->Add("Oviraptor");
    dinosaurs->Add("Tyrannosaurus");

    int herbivores = 5;
    Display(dinosaurs);

    DinoComparer^ dc = gcnew DinoComparer();

    Console::WriteLine("\nSort a range with the alternate comparer:");
    dinosaurs->Sort(0, herbivores, dc);
    Display(dinosaurs);

    Console::WriteLine("\nBinarySearch a range and Insert \"{0}\":",
            "Brachiosaurus");

    int index = dinosaurs->BinarySearch(0, herbivores, "Brachiosaurus", dc);

    if (index < 0)
    {
        dinosaurs->Insert(~index, "Brachiosaurus");
        herbivores++;
    }

    Display(dinosaurs);
}

/* This code example produces the following output:

Pachycephalosaurus
Parasauralophus
Amargasaurus
Galimimus
Mamenchisaurus
Deinonychus
Oviraptor
Tyrannosaurus

Sort a range with the alternate comparer:

Galimimus
Amargasaurus
Mamenchisaurus
Parasauralophus
Pachycephalosaurus
Deinonychus
Oviraptor
Tyrannosaurus

BinarySearch a range and Insert "Brachiosaurus":

Galimimus
Amargasaurus
Brachiosaurus
Mamenchisaurus
Parasauralophus
Pachycephalosaurus
Deinonychus
Oviraptor
Tyrannosaurus
 */
using System;
using System.Collections.Generic;

public class DinoComparer: IComparer<string>
{
    public int Compare(string x, string y)
    {
        if (x == null)
        {
            if (y == null)
            {
                // If x is null and y is null, they're
                // equal. 
                return 0;
            }
            else
            {
                // If x is null and y is not null, y
                // is greater. 
                return -1;
            }
        }
        else
        {
            // If x is not null...
            //
            if (y == null)
                // ...and y is null, x is greater.
            {
                return 1;
            }
            else
            {
                // ...and y is not null, compare the 
                // lengths of the two strings.
                //
                int retval = x.Length.CompareTo(y.Length);

                if (retval != 0)
                {
                    // If the strings are not of equal length,
                    // the longer string is greater.
                    //
                    return retval;
                }
                else
                {
                    // If the strings are of equal length,
                    // sort them with ordinary string comparison.
                    //
                    return x.CompareTo(y);
                }
            }
        }
    }
}

public class Example
{
    public static void Main()
    {
        List<string> dinosaurs = new List<string>();

        dinosaurs.Add("Pachycephalosaurus");
        dinosaurs.Add("Parasauralophus");
        dinosaurs.Add("Amargasaurus");
        dinosaurs.Add("Galimimus");
        dinosaurs.Add("Mamenchisaurus");
        dinosaurs.Add("Deinonychus");
        dinosaurs.Add("Oviraptor");
        dinosaurs.Add("Tyrannosaurus");

        int herbivores = 5;
        Display(dinosaurs);

        DinoComparer dc = new DinoComparer();

        Console.WriteLine("\nSort a range with the alternate comparer:");
        dinosaurs.Sort(0, herbivores, dc);
        Display(dinosaurs);

        Console.WriteLine("\nBinarySearch a range and Insert \"{0}\":",
            "Brachiosaurus");

        int index = dinosaurs.BinarySearch(0, herbivores, "Brachiosaurus", dc);

        if (index < 0)
        {
            dinosaurs.Insert(~index, "Brachiosaurus");
            herbivores++;
        }

        Display(dinosaurs);
    }

    private static void Display(List<string> list)
    {
        Console.WriteLine();
        foreach( string s in list )
        {
            Console.WriteLine(s);
        }
    }
}

/* This code example produces the following output:

Pachycephalosaurus
Parasauralophus
Amargasaurus
Galimimus
Mamenchisaurus
Deinonychus
Oviraptor
Tyrannosaurus

Sort a range with the alternate comparer:

Galimimus
Amargasaurus
Mamenchisaurus
Parasauralophus
Pachycephalosaurus
Deinonychus
Oviraptor
Tyrannosaurus

BinarySearch a range and Insert "Brachiosaurus":

Galimimus
Amargasaurus
Brachiosaurus
Mamenchisaurus
Parasauralophus
Pachycephalosaurus
Deinonychus
Oviraptor
Tyrannosaurus
 */
Imports System
Imports System.Collections.Generic

Public Class DinoComparer
    Implements IComparer(Of String)

    Public Function Compare(ByVal x As String, _
        ByVal y As String) As Integer _
        Implements IComparer(Of String).Compare

        If x Is Nothing Then
            If y Is Nothing Then 
                ' If x is Nothing and y is Nothing, they're
                ' equal. 
                Return 0
            Else
                ' If x is Nothing and y is not Nothing, y
                ' is greater. 
                Return -1
            End If
        Else
            ' If x is not Nothing...
            '
            If y Is Nothing Then
                ' ...and y is Nothing, x is greater.
                Return 1
            Else
                ' ...and y is not Nothing, compare the 
                ' lengths of the two strings.
                '
                Dim retval As Integer = _
                    x.Length.CompareTo(y.Length)

                If retval <> 0 Then 
                    ' If the strings are not of equal length,
                    ' the longer string is greater.
                    '
                    Return retval
                Else
                    ' If the strings are of equal length,
                    ' sort them with ordinary string comparison.
                    '
                    Return x.CompareTo(y)
                End If
            End If
        End If
    End Function
End Class

Public Class Example

    Public Shared Sub Main()

        Dim dinosaurs As New List(Of String)

        dinosaurs.Add("Pachycephalosaurus")
        dinosaurs.Add("Parasauralophus")
        dinosaurs.Add("Amargasaurus")
        dinosaurs.Add("Galimimus")
        dinosaurs.Add("Mamenchisaurus")
        dinosaurs.Add("Deinonychus")
        dinosaurs.Add("Oviraptor")
        dinosaurs.Add("Tyrannosaurus")

        Dim herbivores As Integer = 5
        Display(dinosaurs)

        Dim dc As New DinoComparer

        Console.WriteLine(vbLf & _
            "Sort a range with the alternate comparer:")
        dinosaurs.Sort(0, herbivores, dc)
        Display(dinosaurs)

        Console.WriteLine(vbLf & _
            "BinarySearch a range and Insert ""{0}"":", _
            "Brachiosaurus")

        Dim index As Integer = _
            dinosaurs.BinarySearch(0, herbivores, "Brachiosaurus", dc)

        If index < 0 Then
            index = index Xor -1
            dinosaurs.Insert(index, "Brachiosaurus")
            herbivores += 1
        End If

        Display(dinosaurs)

    End Sub

    Private Shared Sub Display(ByVal lis As List(Of String))
        Console.WriteLine()
        For Each s As String In lis
            Console.WriteLine(s)
        Next
    End Sub
End Class

' This code example produces the following output:
'
'Pachycephalosaurus
'Parasauralophus
'Amargasaurus
'Galimimus
'Mamenchisaurus
'Deinonychus
'Oviraptor
'Tyrannosaurus
'
'Sort a range with the alternate comparer:
'
'Galimimus
'Amargasaurus
'Mamenchisaurus
'Parasauralophus
'Pachycephalosaurus
'Deinonychus
'Oviraptor
'Tyrannosaurus
'
'BinarySearch a range and Insert "Brachiosaurus":
'
'Galimimus
'Amargasaurus
'Brachiosaurus
'Mamenchisaurus
'Parasauralophus
'Pachycephalosaurus
'Deinonychus
'Oviraptor
'Tyrannosaurus

Comentarios

Si comparer se proporciona, los elementos List<T> de se ordenan utilizando la implementación de IComparer<T> especificada.If comparer is provided, the elements of the List<T> are sorted using the specified IComparer<T> implementation.

Si comparer es null ,elIComparable<T> comparador predeterminado T compruebasieltipoimplementalainterfazgenéricayutilizaesaimplementación,siestádisponible.Comparer<T>.DefaultIf comparer is null, the default comparer Comparer<T>.Default checks whether type T implements the IComparable<T> generic interface and uses that implementation, if available. Si no es Comparer<T>.Default así, comprueba T si el tipo IComparable implementa la interfaz.If not, Comparer<T>.Default checks whether type T implements the IComparable interface. Si el T tipo no implementa ninguna de las Comparer<T>.Default interfaces, produce InvalidOperationExceptionuna excepción.If type T does not implement either interface, Comparer<T>.Default throws an InvalidOperationException.

Este método usa Array.Sort, que aplica el orden introspectiva de la siguiente manera:This method uses Array.Sort, which applies the introspective sort as follows:

  • Si el tamaño de la partición es inferior a 16 elementos, usa un algoritmo de ordenación de inserción.If the partition size is fewer than 16 elements, it uses an insertion sort algorithm

  • Si el número de particiones supera 2 log n, donde n es el intervalo de la matriz de entrada, usa un algoritmo Heapsort .If the number of partitions exceeds 2 log n, where n is the range of the input array, it uses a Heapsort algorithm.

  • De lo contrario, usa un algoritmo Quicksort.Otherwise, it uses a Quicksort algorithm.

Esta implementación realiza una ordenación inestable; es decir, si dos elementos son iguales, es posible que no se conserve su orden.This implementation performs an unstable sort; that is, if two elements are equal, their order might not be preserved. Por el contrario, una ordenación estable conserva el orden de los elementos que son iguales.In contrast, a stable sort preserves the order of elements that are equal.

En promedio, este método es una operación o (n log n), donde n es Count; en el peor de los casos, es una operación o (n2).On average, this method is an O(n log n) operation, where n is Count; in the worst case it is an O(n2) operation.

Consulte también:

Sort() Sort() Sort() Sort()

Ordena los elementos de todo el objeto List<T> utilizando el comparador predeterminado.Sorts the elements in the entire List<T> using the default comparer.

public:
 void Sort();
public void Sort ();
member this.Sort : unit -> unit
Public Sub Sort ()

Excepciones

El comparador predeterminado Default no puede encontrar una implementación de la interfaz genérica IComparable<T> o de la interfaz IComparable para el tipo T.The default comparer Default cannot find an implementation of the IComparable<T> generic interface or the IComparable interface for type T.

Ejemplos

En el ejemplo siguiente se agregan algunos List<String> nombres a un objeto, se muestra la lista en orden sin ordenar Sort , se llama al método y, a continuación, se muestra la lista ordenada.The following example adds some names to a List<String> object, displays the list in unsorted order, calls the Sort method, and then displays the sorted list.

using System;
using System.Collections.Generic;

public class Example
{
   public static void Main()
   {
      String[] names = { "Samuel", "Dakota", "Koani", "Saya", "Vanya", "Jody",
                         "Yiska", "Yuma", "Jody", "Nikita" };
      var nameList = new List<String>();
      nameList.AddRange(names);
      Console.WriteLine("List in unsorted order: ");
      foreach (var name in nameList)
         Console.Write("   {0}", name);

      Console.WriteLine(Environment.NewLine);

      nameList.Sort();
      Console.WriteLine("List in sorted order: ");
      foreach (var name in nameList)
         Console.Write("   {0}", name);

      Console.WriteLine();
   }
}
// The example displays the following output:
//    List in unsorted order:
//       Samuel   Dakota   Koani   Saya   Vanya   Jody   Yiska   Yuma   Jody   Nikita
//
//    List in sorted order:
//       Dakota   Jody   Jody   Koani   Nikita   Samuel   Saya   Vanya   Yiska   Yuma
Imports System.Collections.Generic

Module Example
   Public Sub Main()
      Dim names() As String = { "Samuel", "Dakota", "Koani", "Saya",
                                "Vanya", "Jody", "Yiska", "Yuma", 
                                "Jody", "Nikita" }
      Dim nameList As New List(Of String)()
      nameList.AddRange(names)
      Console.WriteLine("List in unsorted order: ")
      For Each name In nameList
         Console.Write("   {0}", name)
      Next
      Console.WriteLine(vbCrLf)

      nameList.Sort()
      Console.WriteLine("List in sorted order: ")
      For Each name In nameList
         Console.Write("   {0}", name)
      Next
      Console.WriteLine()
    End Sub
End Module
' The example displays the following output:
'    List in unsorted order:
'       Samuel   Dakota   Koani   Saya   Vanya   Jody   Yiska   Yuma   Jody   Nikita
'
'    List in sorted order:
'       Dakota   Jody   Jody   Koani   Nikita   Samuel   Saya   Vanya   Yiska   Yuma

En el código siguiente se Sort() muestran Sort(Comparison<T>) las sobrecargas de los métodos y en un objeto comercial simple.The following code demonstrates the Sort() and Sort(Comparison<T>) method overloads on a simple business object. La llamada Sort() al método provoca el uso del comparador predeterminado para el tipo de elemento y el Sort(Comparison<T>) método se implementa mediante un método anónimo.Calling the Sort() method results in the use of the default comparer for the Part type, and the Sort(Comparison<T>) method is implemented by using an anonymous method.

using System;
using System.Collections.Generic;
// Simple business object. A PartId is used to identify the type of part 
// but the part name can change. 
public class Part : IEquatable<Part> , IComparable<Part>
{
    public string PartName { get; set; }

    public int PartId { get; set; }

    public override string ToString()
    {
        return "ID: " + PartId + "   Name: " + PartName;
    }
    public override bool Equals(object obj)
    {
        if (obj == null) return false;
        Part objAsPart = obj as Part;
        if (objAsPart == null) return false;
        else return Equals(objAsPart);
    }
    public int SortByNameAscending(string name1, string name2)
    {
        
        return name1.CompareTo(name2);
    }

    // Default comparer for Part type.
    public int CompareTo(Part comparePart)
    {
          // A null value means that this object is greater.
        if (comparePart == null)
            return 1;
            
        else
            return this.PartId.CompareTo(comparePart.PartId);
    }
    public override int GetHashCode()
    {
        return PartId;
    }
    public bool Equals(Part other)
    {
        if (other == null) return false;
        return (this.PartId.Equals(other.PartId));
    }
    // Should also override == and != operators.

}
public class Example
{
    public static void Main()
    {
        // Create a list of parts.
        List<Part> parts = new List<Part>();

        // Add parts to the list.
        parts.Add(new Part() { PartName = "regular seat", PartId = 1434 });
        parts.Add(new Part() { PartName= "crank arm", PartId = 1234 });
        parts.Add(new Part() { PartName = "shift lever", PartId = 1634 }); ;
        // Name intentionally left null.
        parts.Add(new Part() {  PartId = 1334 });
        parts.Add(new Part() { PartName = "banana seat", PartId = 1444 });
        parts.Add(new Part() { PartName = "cassette", PartId = 1534 });
       

        // Write out the parts in the list. This will call the overridden 
        // ToString method in the Part class.
        Console.WriteLine("\nBefore sort:");
        foreach (Part aPart in parts)
        {
            Console.WriteLine(aPart);
        }


        // Call Sort on the list. This will use the 
        // default comparer, which is the Compare method 
        // implemented on Part.
        parts.Sort();


        Console.WriteLine("\nAfter sort by part number:");
        foreach (Part aPart in parts)
        {
            Console.WriteLine(aPart);
        }
       
        // This shows calling the Sort(Comparison(T) overload using 
        // an anonymous method for the Comparison delegate. 
        // This method treats null as the lesser of two values.
        parts.Sort(delegate(Part x, Part y)
        {
            if (x.PartName == null && y.PartName == null) return 0;
            else if (x.PartName == null) return -1;
            else if (y.PartName == null) return 1;
            else return x.PartName.CompareTo(y.PartName);
        });

        Console.WriteLine("\nAfter sort by name:");
        foreach (Part aPart in parts)
        {
            Console.WriteLine(aPart);
        }
       
        /*
       
            Before sort:
		ID: 1434   Name: regular seat
		ID: 1234   Name: crank arm
		ID: 1634   Name: shift lever
		ID: 1334   Name:
		ID: 1444   Name: banana seat
		ID: 1534   Name: cassette

	    After sort by part number:
		ID: 1234   Name: crank arm
		ID: 1334   Name:
		ID: 1434   Name: regular seat
		ID: 1444   Name: banana seat
		ID: 1534   Name: cassette
		ID: 1634   Name: shift lever

	    After sort by name:
		ID: 1334   Name:
		ID: 1444   Name: banana seat
		ID: 1534   Name: cassette
		ID: 1234   Name: crank arm
		ID: 1434   Name: regular seat
		ID: 1634   Name: shift lever

         */

    }
}
Imports System.Collections.Generic
' Simple business object. A PartId is used to identify the type of part 
' but the part name can change. 
Public Class Part
    Implements IEquatable(Of Part)
    Implements IComparable(Of Part)
    Public Property PartName() As String
        Get
            Return m_PartName
        End Get
        Set(value As String)
            m_PartName = Value
        End Set
    End Property
    Private m_PartName As String

    Public Property PartId() As Integer
        Get
            Return m_PartId
        End Get
        Set(value As Integer)
            m_PartId = Value
        End Set
    End Property
    Private m_PartId As Integer

    Public Overrides Function ToString() As String
        Return "ID: " & PartId & "   Name: " & PartName
    End Function

    Public Overrides Function Equals(obj As Object) As Boolean
        If obj Is Nothing Then
            Return False
        End If
        Dim objAsPart As Part = TryCast(obj, Part)
        If objAsPart Is Nothing Then
            Return False
        Else
            Return Equals(objAsPart)
        End If
    End Function

    Public Function SortByNameAscending(name1 As String, name2 As String) As Integer

        Return name1.CompareTo(name2)
    End Function

    ' Default comparer for Part.
    Public Function CompareTo(comparePart As Part) As Integer _
            Implements IComparable(Of ListSortVB.Part).CompareTo
        ' A null value means that this object is greater.
        If comparePart Is Nothing Then
            Return 1
        Else

            Return Me.PartId.CompareTo(comparePart.PartId)
        End If
    End Function
    Public Overrides Function GetHashCode() As Integer
        Return PartId
    End Function
    Public Overloads Function Equals(other As Part) As Boolean Implements IEquatable(Of ListSortVB.Part).Equals
        If other Is Nothing Then
            Return False
        End If
        Return (Me.PartId.Equals(other.PartId))
    End Function
    ' Should also override == and != operators.

End Class
Public Class Example
    Public Shared Sub Main()
        ' Create a list of parts.
        Dim parts As New List(Of Part)()

        ' Add parts to the list.
        parts.Add(New Part() With { _
             .PartName = "regular seat", _
             .PartId = 1434 _
        })
        parts.Add(New Part() With { _
             .PartName = "crank arm", _
             .PartId = 1234 _
        })
        parts.Add(New Part() With { _
             .PartName = "shift lever", _
             .PartId = 1634 _
        })


        ' Name intentionally left null.
        parts.Add(New Part() With { _
             .PartId = 1334 _
        })
        parts.Add(New Part() With { _
             .PartName = "banana seat", _
             .PartId = 1444 _
        })
        parts.Add(New Part() With { _
             .PartName = "cassette", _
             .PartId = 1534 _
        })


        ' Write out the parts in the list. This will call the overridden 
        ' ToString method in the Part class.
        Console.WriteLine(vbLf & "Before sort:")
        For Each aPart As Part In parts
            Console.WriteLine(aPart)
        Next


        ' Call Sort on the list. This will use the 
        ' default comparer, which is the Compare method 
        ' implemented on Part.
        parts.Sort()


        Console.WriteLine(vbLf & "After sort by part number:")
        For Each aPart As Part In parts
            Console.WriteLine(aPart)
        Next

        ' This shows calling the Sort(Comparison(T) overload using 
        ' an anonymous delegate method. 
        ' This method treats null as the lesser of two values.
        parts.Sort(Function(x As Part, y As Part)
                             If x.PartName Is Nothing AndAlso y.PartName Is Nothing Then
                                 Return 0
                             ElseIf x.PartName Is Nothing Then
                                 Return -1
                             ElseIf y.PartName Is Nothing Then
                                 Return 1
                             Else
                                 Return x.PartName.CompareTo(y.PartName)
                             End If
                         End Function)
        

        Console.WriteLine(vbLf & "After sort by name:")
        For Each aPart As Part In parts
            Console.WriteLine(aPart)
        Next

        '
        '        
        '            Before sort:
        '            ID: 1434   Name: regular seat
        '            ID: 1234   Name: crank arm
        '            ID: 1634   Name: shift lever
        '            ID: 1334   Name:
        '            ID: 1444   Name: banana seat
        '            ID: 1534   Name: cassette
        '
        '            After sort by part number:
        '            ID: 1234   Name: crank arm
        '            ID: 1334   Name:
        '            ID: 1434   Name: regular seat
        '            ID: 1444   Name: banana seat
        '            ID: 1534   Name: cassette
        '            ID: 1634   Name: shift lever
        '
        '            After sort by name:
        '            ID: 1334   Name:
        '            ID: 1444   Name: banana seat
        '            ID: 1534   Name: cassette
        '            ID: 1234   Name: crank arm
        '            ID: 1434   Name: regular seat
        '            ID: 1634   Name: shift lever

    End Sub
End Class

En el ejemplo siguiente se Sort() muestra la sobrecarga del BinarySearch(T) método y la sobrecarga del método.The following example demonstrates the Sort() method overload and the BinarySearch(T) method overload. Un List<T> de cadenas se crea y rellena con cuatro cadenas, en ningún orden determinado.A List<T> of strings is created and populated with four strings, in no particular order. La lista se muestra, se ordena y se muestra de nuevo.The list is displayed, sorted, and displayed again.

La BinarySearch(T) sobrecarga del método se utiliza para buscar dos cadenas que no están en la lista y el Insert método se usa para insertarlas.The BinarySearch(T) method overload is then used to search for two strings that are not in the list, and the Insert method is used to insert them. El valor devuelto del BinarySearch método es negativo en cada caso, porque las cadenas no están en la lista.The return value of the BinarySearch method is negative in each case, because the strings are not in the list. Al tomar el complemento bit a bit (el C# operador ~ C++en Xor y visual,-1 en Visual Basic) de este número negativo, se genera el índice del primer elemento de la lista que es mayor que la cadena de búsqueda y se inserta en esta ubicación. conserva el criterio de ordenación.Taking the bitwise complement (the ~ operator in C# and Visual C++, Xor -1 in Visual Basic) of this negative number produces the index of the first element in the list that is larger than the search string, and inserting at this location preserves the sort order. La segunda cadena de búsqueda es mayor que cualquier elemento de la lista, por lo que la posición de inserción se encuentra al final de la lista.The second search string is larger than any element in the list, so the insertion position is at the end of the list.

using namespace System;
using namespace System::Collections::Generic;

void main()
{
    List<String^>^ dinosaurs = gcnew List<String^>();

    dinosaurs->Add("Pachycephalosaurus");
    dinosaurs->Add("Amargasaurus");
    dinosaurs->Add("Mamenchisaurus");
    dinosaurs->Add("Deinonychus");

    Console::WriteLine();
    for each(String^ dinosaur in dinosaurs)
    {
        Console::WriteLine(dinosaur);
    }

    Console::WriteLine("\nSort");
    dinosaurs->Sort();

    Console::WriteLine();
    for each(String^ dinosaur in dinosaurs)
    {
        Console::WriteLine(dinosaur);
    }

    Console::WriteLine("\nBinarySearch and Insert \"Coelophysis\":");
    int index = dinosaurs->BinarySearch("Coelophysis");
    if (index < 0)
    {
        dinosaurs->Insert(~index, "Coelophysis");
    }

    Console::WriteLine();
    for each(String^ dinosaur in dinosaurs)
    {
        Console::WriteLine(dinosaur);
    }

    Console::WriteLine("\nBinarySearch and Insert \"Tyrannosaurus\":");
    index = dinosaurs->BinarySearch("Tyrannosaurus");
    if (index < 0)
    {
        dinosaurs->Insert(~index, "Tyrannosaurus");
    }

    Console::WriteLine();
    for each(String^ dinosaur in dinosaurs)
    {
        Console::WriteLine(dinosaur);
    }
}

/* This code example produces the following output:

Pachycephalosaurus
Amargasaurus
Mamenchisaurus
Deinonychus

Sort

Amargasaurus
Deinonychus
Mamenchisaurus
Pachycephalosaurus

BinarySearch and Insert "Coelophysis":

Amargasaurus
Coelophysis
Deinonychus
Mamenchisaurus
Pachycephalosaurus

BinarySearch and Insert "Tyrannosaurus":

Amargasaurus
Coelophysis
Deinonychus
Mamenchisaurus
Pachycephalosaurus
Tyrannosaurus
 */
using System;
using System.Collections.Generic;

public class Example
{
    public static void Main()
    {
        List<string> dinosaurs = new List<string>();

        dinosaurs.Add("Pachycephalosaurus");
        dinosaurs.Add("Amargasaurus");
        dinosaurs.Add("Mamenchisaurus");
        dinosaurs.Add("Deinonychus");

        Console.WriteLine();
        foreach(string dinosaur in dinosaurs)
        {
            Console.WriteLine(dinosaur);
        }

        Console.WriteLine("\nSort");
        dinosaurs.Sort();

        Console.WriteLine();
        foreach(string dinosaur in dinosaurs)
        {
            Console.WriteLine(dinosaur);
        }

        Console.WriteLine("\nBinarySearch and Insert \"Coelophysis\":");
        int index = dinosaurs.BinarySearch("Coelophysis");
        if (index < 0)
        {
            dinosaurs.Insert(~index, "Coelophysis");
        }

        Console.WriteLine();
        foreach(string dinosaur in dinosaurs)
        {
            Console.WriteLine(dinosaur);
        }

        Console.WriteLine("\nBinarySearch and Insert \"Tyrannosaurus\":");
        index = dinosaurs.BinarySearch("Tyrannosaurus");
        if (index < 0)
        {
            dinosaurs.Insert(~index, "Tyrannosaurus");
        }

        Console.WriteLine();
        foreach(string dinosaur in dinosaurs)
        {
            Console.WriteLine(dinosaur);
        }
    }
}

/* This code example produces the following output:

Pachycephalosaurus
Amargasaurus
Mamenchisaurus
Deinonychus

Sort

Amargasaurus
Deinonychus
Mamenchisaurus
Pachycephalosaurus

BinarySearch and Insert "Coelophysis":

Amargasaurus
Coelophysis
Deinonychus
Mamenchisaurus
Pachycephalosaurus

BinarySearch and Insert "Tyrannosaurus":

Amargasaurus
Coelophysis
Deinonychus
Mamenchisaurus
Pachycephalosaurus
Tyrannosaurus
 */
Imports System
Imports System.Collections.Generic

Public Class Example

    Public Shared Sub Main()

        Dim dinosaurs As New List(Of String)

        dinosaurs.Add("Pachycephalosaurus")
        dinosaurs.Add("Amargasaurus")
        dinosaurs.Add("Mamenchisaurus")
        dinosaurs.Add("Deinonychus")

        Console.WriteLine()
        For Each dinosaur As String In dinosaurs
            Console.WriteLine(dinosaur)
        Next

        Console.WriteLine(vbLf & "Sort")
        dinosaurs.Sort

        Console.WriteLine()
        For Each dinosaur As String In dinosaurs
            Console.WriteLine(dinosaur)
        Next

        Console.WriteLine(vbLf & _
            "BinarySearch and Insert ""Coelophysis"":")
        Dim index As Integer = dinosaurs.BinarySearch("Coelophysis")
        If index < 0 Then
            index = index Xor -1
            dinosaurs.Insert(index, "Coelophysis")
        End If

        Console.WriteLine()
        For Each dinosaur As String In dinosaurs
            Console.WriteLine(dinosaur)
        Next

        Console.WriteLine(vbLf & _
            "BinarySearch and Insert ""Tyrannosaurus"":")
        index = dinosaurs.BinarySearch("Tyrannosaurus")
        If index < 0 Then
            index = index Xor -1
            dinosaurs.Insert(index, "Tyrannosaurus")
        End If

        Console.WriteLine()
        For Each dinosaur As String In dinosaurs
            Console.WriteLine(dinosaur)
        Next

    End Sub
End Class

' This code example produces the following output:
'
'Pachycephalosaurus
'Amargasaurus
'Mamenchisaurus
'Deinonychus
'
'Sort
'
'Amargasaurus
'Deinonychus
'Mamenchisaurus
'Pachycephalosaurus
'
'BinarySearch and Insert "Coelophysis":
'
'Amargasaurus
'Coelophysis
'Deinonychus
'Mamenchisaurus
'Pachycephalosaurus
'
'BinarySearch and Insert "Tyrannosaurus":
'
'Amargasaurus
'Coelophysis
'Deinonychus
'Mamenchisaurus
'Pachycephalosaurus
'Tyrannosaurus

Comentarios

Este método utiliza el comparador Comparer<T>.Default predeterminado para T el tipo con el fin de determinar el orden de los elementos de lista.This method uses the default comparer Comparer<T>.Default for type T to determine the order of list elements. La Comparer<T>.Default propiedad comprueba si el T tipo implementa la IComparable<T> interfaz genérica y utiliza esa implementación, si está disponible.The Comparer<T>.Default property checks whether type T implements the IComparable<T> generic interface and uses that implementation, if available. Si no es Comparer<T>.Default así, comprueba T si el tipo IComparable implementa la interfaz.If not, Comparer<T>.Default checks whether type T implements the IComparable interface. Si el T tipo no implementa ninguna de las Comparer<T>.Default interfaces, produce InvalidOperationExceptionuna excepción.If type T does not implement either interface, Comparer<T>.Default throws an InvalidOperationException.

Este método usa el Array.Sort método, que aplica la ordenación de introspectiva como se indica a continuación:This method uses the Array.Sort method, which applies the introspective sort as follows:

  • Si el tamaño de la partición es inferior a 16 elementos, usa un algoritmo de ordenación de inserción.If the partition size is fewer than 16 elements, it uses an insertion sort algorithm.

  • Si el número de particiones supera 2 log n, donde n es el intervalo de la matriz de entrada, usa un algoritmo Heapsort.If the number of partitions exceeds 2 log n, where n is the range of the input array, it uses a Heapsort algorithm.

  • De lo contrario, usa un algoritmo Quicksort.Otherwise, it uses a Quicksort algorithm.

Esta implementación realiza una ordenación inestable; es decir, si dos elementos son iguales, es posible que no se conserve su orden.This implementation performs an unstable sort; that is, if two elements are equal, their order might not be preserved. Por el contrario, una ordenación estable conserva el orden de los elementos que son iguales.In contrast, a stable sort preserves the order of elements that are equal.

En promedio, este método es una operación o (n log n), donde n es Count; en el peor de los casos, es una operación o (n2).On average, this method is an O(n log n) operation, where n is Count; in the worst case it is an O(n2) operation.

Consulte también:

Sort(IComparer<T>) Sort(IComparer<T>) Sort(IComparer<T>) Sort(IComparer<T>)

Ordena los elementos en la List<T> completa usando el comparador especificado.Sorts the elements in the entire List<T> using the specified comparer.

public:
 void Sort(System::Collections::Generic::IComparer<T> ^ comparer);
public void Sort (System.Collections.Generic.IComparer<T> comparer);
member this.Sort : System.Collections.Generic.IComparer<'T> -> unit
Public Sub Sort (comparer As IComparer(Of T))

Parámetros

comparer
IComparer<T> IComparer<T> IComparer<T> IComparer<T>

Implementación de IComparer<T> que se va a utilizar al comparar elementos, o null para utilizar el comparador predeterminado Default.The IComparer<T> implementation to use when comparing elements, or null to use the default comparer Default.

Excepciones

comparer es null, y el comparador predeterminado Default no puede encontrar una implementación de la interfaz genérica IComparable<T> o la interfaz IComparable del tipo T.comparer is null, and the default comparer Default cannot find implementation of the IComparable<T> generic interface or the IComparable interface for type T.

La implementación de comparer produjo un error durante la ordenación.The implementation of comparer caused an error during the sort. Por ejemplo, es posible que comparer no devuelva 0 al comparar un elemento consigo mismo.For example, comparer might not return 0 when comparing an item with itself.

Ejemplos

En el ejemplo siguiente se Sort(IComparer<T>) muestra la sobrecarga del BinarySearch(T, IComparer<T>) método y la sobrecarga del método.The following example demonstrates the Sort(IComparer<T>) method overload and the BinarySearch(T, IComparer<T>) method overload.

En el ejemplo se define un comparador alternativo para las cadenas denominadas DinoCompare IComparer<string> ,IComparer(Of String) que implementa la IComparer<String^> interfaz genérica C++(en Visual Basic, en visual).The example defines an alternative comparer for strings named DinoCompare, which implements the IComparer<string> (IComparer(Of String) in Visual Basic, IComparer<String^> in Visual C++) generic interface. El comparador funciona de la siguiente manera: En primer lugar, se prueban nulllas comparaciones de y una referencia nula se trata como menor que un valor no NULL.The comparer works as follows: First, the comparands are tested for null, and a null reference is treated as less than a non-null. En segundo lugar, se comparan las longitudes de cadena y se considera que la cadena más larga es mayor.Second, the string lengths are compared, and the longer string is deemed to be greater. En tercer lugar, si las longitudes son iguales, se usa la comparación de cadenas ordinaria.Third, if the lengths are equal, ordinary string comparison is used.

Un List<T> de cadenas se crea y rellena con cuatro cadenas, en ningún orden determinado.A List<T> of strings is created and populated with four strings, in no particular order. La lista se muestra, se ordena mediante el comparador alternativo y se muestra de nuevo.The list is displayed, sorted using the alternate comparer, and displayed again.

A BinarySearch(T, IComparer<T>) continuación, la sobrecarga del método se utiliza para buscar varias cadenas que no están en la lista, empleando el comparador alternativo.The BinarySearch(T, IComparer<T>) method overload is then used to search for several strings that are not in the list, employing the alternate comparer. El Insert método se usa para insertar las cadenas.The Insert method is used to insert the strings. Estos dos métodos se encuentran en la función denominada SearchAndInsert, junto con el código para tomar el complemento bit a bit (el C# operador ~ C++en Xor y visual,-1 en Visual Basic) del número negativo BinarySearch(T, IComparer<T>) devuelto por y usarlo como índice para insertar la nueva cadena.These two methods are located in the function named SearchAndInsert, along with code to take the bitwise complement (the ~ operator in C# and Visual C++, Xor -1 in Visual Basic) of the negative number returned by BinarySearch(T, IComparer<T>) and use it as an index for inserting the new string.

using namespace System;
using namespace System::Collections::Generic;

public ref class DinoComparer: IComparer<String^>
{
public:
    virtual int Compare(String^ x, String^ y)
    {
        if (x == nullptr)
        {
            if (y == nullptr)
            {
                // If x is null and y is null, they're
                // equal. 
                return 0;
            }
            else
            {
                // If x is null and y is not null, y
                // is greater. 
                return -1;
            }
        }
        else
        {
            // If x is not null...
            //
            if (y == nullptr)
                // ...and y is null, x is greater.
            {
                return 1;
            }
            else
            {
                // ...and y is not null, compare the 
                // lengths of the two strings.
                //
                int retval = x->Length.CompareTo(y->Length);

                if (retval != 0)
                {
                    // If the strings are not of equal length,
                    // the longer string is greater.
                    //
                    return retval;
                }
                else
                {
                    // If the strings are of equal length,
                    // sort them with ordinary string comparison.
                    //
                    return x->CompareTo(y);
                }
            }
        }
    }
};

void SearchAndInsert(List<String^>^ list, String^ insert, 
    DinoComparer^ dc)
{
    Console::WriteLine("\nBinarySearch and Insert \"{0}\":", insert);

    int index = list->BinarySearch(insert, dc);

    if (index < 0)
    {
        list->Insert(~index, insert);
    }
};

void Display(List<String^>^ list)
{
    Console::WriteLine();
    for each(String^ s in list)
    {
        Console::WriteLine(s);
    }
};

void main()
{
    List<String^>^ dinosaurs = gcnew List<String^>();
    dinosaurs->Add("Pachycephalosaurus");
    dinosaurs->Add("Amargasaurus");
    dinosaurs->Add("Mamenchisaurus");
    dinosaurs->Add("Deinonychus");
    Display(dinosaurs);

    DinoComparer^ dc = gcnew DinoComparer();

    Console::WriteLine("\nSort with alternate comparer:");
    dinosaurs->Sort(dc);
    Display(dinosaurs);

    SearchAndInsert(dinosaurs, "Coelophysis", dc);
    Display(dinosaurs);

    SearchAndInsert(dinosaurs, "Oviraptor", dc);
    Display(dinosaurs);

    SearchAndInsert(dinosaurs, "Tyrannosaur", dc);
    Display(dinosaurs);

    SearchAndInsert(dinosaurs, nullptr, dc);
    Display(dinosaurs);
}

/* This code example produces the following output:

Pachycephalosaurus
Amargasaurus
Mamenchisaurus
Deinonychus

Sort with alternate comparer:

Deinonychus
Amargasaurus
Mamenchisaurus
Pachycephalosaurus

BinarySearch and Insert "Coelophysis":

Coelophysis
Deinonychus
Amargasaurus
Mamenchisaurus
Pachycephalosaurus

BinarySearch and Insert "Oviraptor":

Oviraptor
Coelophysis
Deinonychus
Amargasaurus
Mamenchisaurus
Pachycephalosaurus

BinarySearch and Insert "Tyrannosaur":

Oviraptor
Coelophysis
Deinonychus
Tyrannosaur
Amargasaurus
Mamenchisaurus
Pachycephalosaurus

BinarySearch and Insert "":


Oviraptor
Coelophysis
Deinonychus
Tyrannosaur
Amargasaurus
Mamenchisaurus
Pachycephalosaurus
 */
using System;
using System.Collections.Generic;

public class DinoComparer: IComparer<string>
{
    public int Compare(string x, string y)
    {
        if (x == null)
        {
            if (y == null)
            {
                // If x is null and y is null, they're
                // equal. 
                return 0;
            }
            else
            {
                // If x is null and y is not null, y
                // is greater. 
                return -1;
            }
        }
        else
        {
            // If x is not null...
            //
            if (y == null)
                // ...and y is null, x is greater.
            {
                return 1;
            }
            else
            {
                // ...and y is not null, compare the 
                // lengths of the two strings.
                //
                int retval = x.Length.CompareTo(y.Length);

                if (retval != 0)
                {
                    // If the strings are not of equal length,
                    // the longer string is greater.
                    //
                    return retval;
                }
                else
                {
                    // If the strings are of equal length,
                    // sort them with ordinary string comparison.
                    //
                    return x.CompareTo(y);
                }
            }
        }
    }
}

public class Example
{
    public static void Main()
    {
        List<string> dinosaurs = new List<string>();
        dinosaurs.Add("Pachycephalosaurus");
        dinosaurs.Add("Amargasaurus");
        dinosaurs.Add("Mamenchisaurus");
        dinosaurs.Add("Deinonychus");
        Display(dinosaurs);

        DinoComparer dc = new DinoComparer();

        Console.WriteLine("\nSort with alternate comparer:");
        dinosaurs.Sort(dc);
        Display(dinosaurs);

        SearchAndInsert(dinosaurs, "Coelophysis", dc);
        Display(dinosaurs);

        SearchAndInsert(dinosaurs, "Oviraptor", dc);
        Display(dinosaurs);

        SearchAndInsert(dinosaurs, "Tyrannosaur", dc);
        Display(dinosaurs);

        SearchAndInsert(dinosaurs, null, dc);
        Display(dinosaurs);
    }

    private static void SearchAndInsert(List<string> list, 
        string insert, DinoComparer dc)
    {
        Console.WriteLine("\nBinarySearch and Insert \"{0}\":", insert);

        int index = list.BinarySearch(insert, dc);

        if (index < 0)
        {
            list.Insert(~index, insert);
        }
    }

    private static void Display(List<string> list)
    {
        Console.WriteLine();
        foreach( string s in list )
        {
            Console.WriteLine(s);
        }
    }
}

/* This code example produces the following output:

Pachycephalosaurus
Amargasaurus
Mamenchisaurus
Deinonychus

Sort with alternate comparer:

Deinonychus
Amargasaurus
Mamenchisaurus
Pachycephalosaurus

BinarySearch and Insert "Coelophysis":

Coelophysis
Deinonychus
Amargasaurus
Mamenchisaurus
Pachycephalosaurus

BinarySearch and Insert "Oviraptor":

Oviraptor
Coelophysis
Deinonychus
Amargasaurus
Mamenchisaurus
Pachycephalosaurus

BinarySearch and Insert "Tyrannosaur":

Oviraptor
Coelophysis
Deinonychus
Tyrannosaur
Amargasaurus
Mamenchisaurus
Pachycephalosaurus

BinarySearch and Insert "":


Oviraptor
Coelophysis
Deinonychus
Tyrannosaur
Amargasaurus
Mamenchisaurus
Pachycephalosaurus
 */
Imports System
Imports System.Collections.Generic

Public Class DinoComparer
    Implements IComparer(Of String)

    Public Function Compare(ByVal x As String, _
        ByVal y As String) As Integer _
        Implements IComparer(Of String).Compare

        If x Is Nothing Then
            If y Is Nothing Then 
                ' If x is Nothing and y is Nothing, they're
                ' equal. 
                Return 0
            Else
                ' If x is Nothing and y is not Nothing, y
                ' is greater. 
                Return -1
            End If
        Else
            ' If x is not Nothing...
            '
            If y Is Nothing Then
                ' ...and y is Nothing, x is greater.
                Return 1
            Else
                ' ...and y is not Nothing, compare the 
                ' lengths of the two strings.
                '
                Dim retval As Integer = _
                    x.Length.CompareTo(y.Length)

                If retval <> 0 Then 
                    ' If the strings are not of equal length,
                    ' the longer string is greater.
                    '
                    Return retval
                Else
                    ' If the strings are of equal length,
                    ' sort them with ordinary string comparison.
                    '
                    Return x.CompareTo(y)
                End If
            End If
        End If
    End Function
End Class

Public Class Example

    Public Shared Sub Main()

        Dim dinosaurs As New List(Of String)
        dinosaurs.Add("Pachycephalosaurus")
        dinosaurs.Add("Amargasaurus")
        dinosaurs.Add("Mamenchisaurus")
        dinosaurs.Add("Deinonychus")
        Display(dinosaurs)

        Dim dc As New DinoComparer

        Console.WriteLine(vbLf & "Sort with alternate comparer:")
        dinosaurs.Sort(dc)
        Display(dinosaurs)

        SearchAndInsert(dinosaurs, "Coelophysis", dc)
        Display(dinosaurs)

        SearchAndInsert(dinosaurs, "Oviraptor", dc)
        Display(dinosaurs)

        SearchAndInsert(dinosaurs, "Tyrannosaur", dc)
        Display(dinosaurs)

        SearchAndInsert(dinosaurs, Nothing, dc)
        Display(dinosaurs)
    End Sub

    Private Shared Sub SearchAndInsert( _
        ByVal lis As List(Of String), _
        ByVal insert As String, ByVal dc As DinoComparer)

        Console.WriteLine(vbLf & _
            "BinarySearch and Insert ""{0}"":", insert)

        Dim index As Integer = lis.BinarySearch(insert, dc)

        If index < 0 Then
            index = index Xor -1
            lis.Insert(index, insert)
        End If
    End Sub

    Private Shared Sub Display(ByVal lis As List(Of String))
        Console.WriteLine()
        For Each s As String In lis
            Console.WriteLine(s)
        Next
    End Sub
End Class

' This code example produces the following output:
'
'Pachycephalosaurus
'Amargasaurus
'Mamenchisaurus
'Deinonychus
'
'Sort with alternate comparer:
'
'Deinonychus
'Amargasaurus
'Mamenchisaurus
'Pachycephalosaurus
'
'BinarySearch and Insert "Coelophysis":
'
'Coelophysis
'Deinonychus
'Amargasaurus
'Mamenchisaurus
'Pachycephalosaurus
'
'BinarySearch and Insert "Oviraptor":
'
'Oviraptor
'Coelophysis
'Deinonychus
'Amargasaurus
'Mamenchisaurus
'Pachycephalosaurus
'
'BinarySearch and Insert "Tyrannosaur":
'
'Oviraptor
'Coelophysis
'Deinonychus
'Tyrannosaur
'Amargasaurus
'Mamenchisaurus
'Pachycephalosaurus
'
'BinarySearch and Insert "":
'
'
'Oviraptor
'Coelophysis
'Deinonychus
'Tyrannosaur
'Amargasaurus
'Mamenchisaurus
'Pachycephalosaurus

Comentarios

Si comparer se proporciona, los elementos List<T> de se ordenan utilizando la implementación de IComparer<T> especificada.If comparer is provided, the elements of the List<T> are sorted using the specified IComparer<T> implementation.

Si comparer es null ,elIComparable<T> comparador predeterminado T compruebasieltipoimplementalainterfazgenéricayutilizaesaimplementación,siestádisponible.Comparer<T>.DefaultIf comparer is null, the default comparer Comparer<T>.Default checks whether type T implements the IComparable<T> generic interface and uses that implementation, if available. Si no es Comparer<T>.Default así, comprueba T si el tipo IComparable implementa la interfaz.If not, Comparer<T>.Default checks whether type T implements the IComparable interface. Si el T tipo no implementa ninguna de las Comparer<T>.Default interfaces, produce InvalidOperationExceptionuna excepción.If type T does not implement either interface, Comparer<T>.Default throws an InvalidOperationException.

Este método usa el Array.Sort método, que aplica la ordenación de introspectiva como se indica a continuación:This method uses the Array.Sort method, which applies the introspective sort as follows:

  • Si el tamaño de la partición es inferior a 16 elementos, usa un algoritmo de ordenación de inserción.If the partition size is fewer than 16 elements, it uses an insertion sort algorithm.

  • Si el número de particiones supera 2 log n, donde n es el intervalo de la matriz de entrada, usa un algoritmo Heapsort.If the number of partitions exceeds 2 log n, where n is the range of the input array, it uses a Heapsort algorithm.

  • De lo contrario, usa un algoritmo Quicksort.Otherwise, it uses a Quicksort algorithm.

Esta implementación realiza una ordenación inestable; es decir, si dos elementos son iguales, es posible que no se conserve su orden.This implementation performs an unstable sort; that is, if two elements are equal, their order might not be preserved. Por el contrario, una ordenación estable conserva el orden de los elementos que son iguales.In contrast, a stable sort preserves the order of elements that are equal.

En promedio, este método es una operación o (n log n), donde n es Count; en el peor de los casos, es una operación o (n2).On average, this method is an O(n log n) operation, where n is Count; in the worst case it is an O(n2) operation.

Consulte también:

Se aplica a