RNGCryptoServiceProvider.GetBytes Methode

Definition

Namespace:

System.Security.Cryptography

Assembly:

System.Security.Cryptography.dll

Überlädt

GetBytes(Byte[])	Füllt ein Bytearray mit einer kryptografisch starken Abfolge von Zufallswerten.
GetBytes(Span<Byte>)	Füllt eine Spanne mit kryptografisch starken zufälligen Bytes.
GetBytes(Byte[], Int32, Int32)	Füllt das angegebene Bytearray mit einer kryptografisch starken zufälligen Abfolge von Werten ab einem angegebenen Index für eine angegebene Anzahl von Bytes.

GetBytes(Byte[])

Quelle:

RNGCryptoServiceProvider.cs

Füllt ein Bytearray mit einer kryptografisch starken Abfolge von Zufallswerten.

public:
 override void GetBytes(cli::array <System::Byte> ^ data);

public override void GetBytes (byte[] data);

override this.GetBytes : byte[] -> unit

Public Overrides Sub GetBytes (data As Byte())

Parameter

data

Byte[]

Das Array, das mit einer kryptografisch starken Abfolge von Zufallswerten gefüllt werden soll.

Ausnahmen

CryptographicException

Der kryptografische Dienstanbieter (CSP) kann nicht erworben werden.

ArgumentNullException

data ist null.

Beispiele

Im folgenden Codebeispiel wird gezeigt, wie Sie eine Zufallszahl mit der RNGCryptoServiceProvider Klasse erstellen.

//The following sample uses the Cryptography class to simulate the roll of a dice.

using namespace System;
using namespace System::IO;
using namespace System::Text;
using namespace System::Security::Cryptography;

ref class RNGCSP
{
public:
    // Main method.
    static void Main()
    {
        const int totalRolls = 25000;
        array<int>^ results = gcnew array<int>(6);

        // Roll the dice 25000 times and display
        // the results to the console.
        for (int x = 0; x < totalRolls; x++)
        {
            Byte roll = RollDice((Byte)results->Length);
            results[roll - 1]++;
        }
        for (int i = 0; i < results->Length; ++i)
        {
            Console::WriteLine("{0}: {1} ({2:p1})", i + 1, results[i], (double)results[i] / (double)totalRolls);
        }
    }

    // This method simulates a roll of the dice. The input parameter is the
    // number of sides of the dice.

    static Byte RollDice(Byte numberSides)
    {
        if (numberSides <= 0)
            throw gcnew ArgumentOutOfRangeException("numberSides");
        // Create a new instance of the RNGCryptoServiceProvider.
        RNGCryptoServiceProvider^ rngCsp = gcnew RNGCryptoServiceProvider();
        // Create a byte array to hold the random value.
        array<Byte>^ randomNumber = gcnew array<Byte>(1);
        do
        {
            // Fill the array with a random value.
            rngCsp->GetBytes(randomNumber);
        }
        while (!IsFairRoll(randomNumber[0], numberSides));
        // Return the random number mod the number
        // of sides.  The possible values are zero-
        // based, so we add one.
        return (Byte)((randomNumber[0] % numberSides) + 1);
    }

private:
    static bool IsFairRoll(Byte roll, Byte numSides)
    {
        // There are MaxValue / numSides full sets of numbers that can come up
        // in a single byte.  For instance, if we have a 6 sided die, there are
        // 42 full sets of 1-6 that come up.  The 43rd set is incomplete.
        int fullSetsOfValues = Byte::MaxValue / numSides;

        // If the roll is within this range of fair values, then we let it continue.
        // In the 6 sided die case, a roll between 0 and 251 is allowed.  (We use
        // < rather than <= since the = portion allows through an extra 0 value).
        // 252 through 255 would provide an extra 0, 1, 2, 3 so they are not fair
        // to use.
        return roll < numSides * fullSetsOfValues;
    }
};

int main()
{
    RNGCSP::Main();
}

//The following sample uses the Cryptography class to simulate the roll of a dice.

using System;
using System.IO;
using System.Text;
using System.Security.Cryptography;

class RNGCSP
{
    private static RNGCryptoServiceProvider rngCsp = new RNGCryptoServiceProvider();
    // Main method.
    public static void Main()
    {
        const int totalRolls = 25000;
        int[] results = new int[6];

        // Roll the dice 25000 times and display
        // the results to the console.
        for (int x = 0; x < totalRolls; x++)
        {
            byte roll = RollDice((byte)results.Length);
            results[roll - 1]++;
        }
        for (int i = 0; i < results.Length; ++i)
        {
            Console.WriteLine("{0}: {1} ({2:p1})", i + 1, results[i], (double)results[i] / (double)totalRolls);
        }
        rngCsp.Dispose();
    }

    // This method simulates a roll of the dice. The input parameter is the
    // number of sides of the dice.

    public static byte RollDice(byte numberSides)
    {
        if (numberSides <= 0)
            throw new ArgumentOutOfRangeException("numberSides");

        // Create a byte array to hold the random value.
        byte[] randomNumber = new byte[1];
        do
        {
            // Fill the array with a random value.
            rngCsp.GetBytes(randomNumber);
        }
        while (!IsFairRoll(randomNumber[0], numberSides));
        // Return the random number mod the number
        // of sides.  The possible values are zero-
        // based, so we add one.
        return (byte)((randomNumber[0] % numberSides) + 1);
    }

    private static bool IsFairRoll(byte roll, byte numSides)
    {
        // There are MaxValue / numSides full sets of numbers that can come up
        // in a single byte.  For instance, if we have a 6 sided die, there are
        // 42 full sets of 1-6 that come up.  The 43rd set is incomplete.
        int fullSetsOfValues = Byte.MaxValue / numSides;

        // If the roll is within this range of fair values, then we let it continue.
        // In the 6 sided die case, a roll between 0 and 251 is allowed.  (We use
        // < rather than <= since the = portion allows through an extra 0 value).
        // 252 through 255 would provide an extra 0, 1, 2, 3 so they are not fair
        // to use.
        return roll < numSides * fullSetsOfValues;
    }
}

'The following sample uses the Cryptography class to simulate the roll of a dice.
Imports System.IO
Imports System.Text
Imports System.Security.Cryptography



Class RNGCSP
    Private Shared rngCsp As New RNGCryptoServiceProvider()
    ' Main method.
    Public Shared Sub Main()
        Const totalRolls As Integer = 25000
        Dim results(5) As Integer

        ' Roll the dice 25000 times and display
        ' the results to the console.
        Dim x As Integer
        For x = 0 To totalRolls
            Dim roll As Byte = RollDice(System.Convert.ToByte(results.Length))
            results((roll - 1)) += 1
        Next x
        Dim i As Integer

        While i < results.Length
            Console.WriteLine("{0}: {1} ({2:p1})", i + 1, results(i), System.Convert.ToDouble(results(i)) / System.Convert.ToDouble(totalRolls))
            i += 1
        End While
        rngCsp.Dispose()
    End Sub


    ' This method simulates a roll of the dice. The input parameter is the
    ' number of sides of the dice.
    Public Shared Function RollDice(ByVal numberSides As Byte) As Byte
        If numberSides <= 0 Then
            Throw New ArgumentOutOfRangeException("NumSides")
        End If 
        ' Create a byte array to hold the random value.
        Dim randomNumber(0) As Byte
        Do
            ' Fill the array with a random value.
            rngCsp.GetBytes(randomNumber)
        Loop While Not IsFairRoll(randomNumber(0), numberSides)
        ' Return the random number mod the number
        ' of sides.  The possible values are zero-
        ' based, so we add one.
        Return System.Convert.ToByte(randomNumber(0) Mod numberSides + 1)

    End Function


    Private Shared Function IsFairRoll(ByVal roll As Byte, ByVal numSides As Byte) As Boolean
        ' There are MaxValue / numSides full sets of numbers that can come up
        ' in a single byte.  For instance, if we have a 6 sided die, there are
        ' 42 full sets of 1-6 that come up.  The 43rd set is incomplete.
        Dim fullSetsOfValues As Integer = [Byte].MaxValue / numSides

        ' If the roll is within this range of fair values, then we let it continue.
        ' In the 6 sided die case, a roll between 0 and 251 is allowed.  (We use
        ' < rather than <= since the = portion allows through an extra 0 value).
        ' 252 through 255 would provide an extra 0, 1, 2, 3 so they are not fair
        ' to use.
        Return roll < numSides * fullSetsOfValues

    End Function 'IsFairRoll
End Class

Hinweise

Die Länge des Bytearrays bestimmt, wie viele kryptografisch starke zufällige Bytes erzeugt werden.

Diese Methode ist threadsicher.

Weitere Informationen

• Kryptografiedienste

GetBytes(Span<Byte>)

Quelle:

RNGCryptoServiceProvider.cs

Füllt eine Spanne mit kryptografisch starken zufälligen Bytes.

public:
 override void GetBytes(Span<System::Byte> data);

public override void GetBytes (Span<byte> data);

override this.GetBytes : Span<byte> -> unit

Public Overrides Sub GetBytes (data As Span(Of Byte))

Parameter

data

Span<Byte>

Die Spanne, die mit kryptografisch starken zufälligen Bytes gefüllt werden soll.

GetBytes(Byte[], Int32, Int32)

Quelle:

RNGCryptoServiceProvider.cs

Füllt das angegebene Bytearray mit einer kryptografisch starken zufälligen Abfolge von Werten ab einem angegebenen Index für eine angegebene Anzahl von Bytes.

public:
 override void GetBytes(cli::array <System::Byte> ^ data, int offset, int count);

public override void GetBytes (byte[] data, int offset, int count);

override this.GetBytes : byte[] * int * int -> unit

Public Overrides Sub GetBytes (data As Byte(), offset As Integer, count As Integer)

Parameter

data

Byte[]

Das Array, das mit kryptografisch starken zufälligen Bytes gefüllt werden soll.

offset

Int32

Der Index des Arrays, um den Füllvorgang zu starten.

count

Int32

Die Anzahl der zu füllenden Bytes.

Ausnahmen

ArgumentNullException

data ist null.

ArgumentOutOfRangeException

offset oder count ist kleiner als 0.

ArgumentException

offset plus count überschreitet die Länge der data.