AsymmetricAlgorithm Classe
Definizione
Importante
Alcune informazioni sono relative alla release non definitiva del prodotto, che potrebbe subire modifiche significative prima della release definitiva. Microsoft non riconosce alcuna garanzia, espressa o implicita, in merito alle informazioni qui fornite.
Rappresenta la classe base astratta dalla quale devono ereditare tutte le implementazioni di algoritmi asimmetrici.
public ref class AsymmetricAlgorithm abstract : IDisposablepublic abstract class AsymmetricAlgorithm : IDisposable[System.Runtime.InteropServices.ComVisible(true)]
public abstract class AsymmetricAlgorithm : IDisposabletype AsymmetricAlgorithm = class
interface IDisposable[<System.Runtime.InteropServices.ComVisible(true)>]
type AsymmetricAlgorithm = class
interface IDisposablePublic MustInherit Class AsymmetricAlgorithm
Implements IDisposable- Ereditarietà
-
AsymmetricAlgorithm
- Derivato
- Attributi
- Implementazioni
Esempio
Nell'esempio AsymmetricAlgorithm di codice seguente viene illustrato come implementare un algoritmo asimmetrico personalizzato ereditato dalla classe. Viene fornita una classe aggiuntiva per illustrare come usare la classe personalizzata.
#using <System.Xml.dll>
#using <System.Security.dll>
using namespace System;
using namespace System::Xml;
using namespace System::Text;
using namespace System::Security::Cryptography;
using namespace System::Reflection;
[assembly: AssemblyKeyFile("CustomCrypto.snk")];
[assembly: AssemblyVersion("1.0.0.0")];
[assembly: CLSCompliant(true)];
namespace Contoso
{
// Define a CustomCrypto class that inherits from the AsymmetricAlgorithm
// class.
public ref class CustomCrypto :
public System::Security::Cryptography::AsymmetricAlgorithm
{
// Declare local member variables.
private:
CspParameters^ cryptoServiceParameters;
array<KeySizes^>^ customValidKeySizes;
// Initialize a CustomCrypto with the default key size of 8.
public:
CustomCrypto()
{
customValidKeySizes =
gcnew array<KeySizes^>{gcnew KeySizes(8, 64, 8)};
this->KeySize = 8;
}
// Initialize a CustomCrypto with the specified key size.
public:
CustomCrypto(int keySize)
{
customValidKeySizes =
gcnew array<KeySizes^>{gcnew KeySizes(8, 64, 8)};
this->KeySize = keySize;
}
// Accessor function for keySizes member variable.
public:
property array<KeySizes^>^ LegalKeySizes
{
virtual array<KeySizes^>^ get() override
{
return (array<KeySizes^>^)customValidKeySizes->Clone();
}
}
// Modify the KeySizeValue property inherited from the Asymmetric
// class. Prior to setting the value, ensure it falls within the
// range identified in the local keySizes member variable.
public:
property int KeySize
{
virtual int get() override
{
return KeySizeValue;
}
virtual void set(int value) override
{
for (int i = 0; i < customValidKeySizes->Length; i++)
{
if (customValidKeySizes[i]->SkipSize == 0)
{
if (customValidKeySizes[i]->MinSize == value)
{
KeySizeValue = value;
return;
}
}
else
{
for (int j = customValidKeySizes[i]->MinSize;
j <= customValidKeySizes[i]->MaxSize;
j += customValidKeySizes[i]->SkipSize)
{
if (j == value)
{
KeySizeValue = value;
return;
}
}
}
}
// If the key does not fall within the range identified
// in the keySizes member variable, throw an exception.
throw gcnew CryptographicException("Invalid key size.");
}
}
// Initialize the parameters with default values.
public:
void InitializeParameters()
{
cryptoServiceParameters = gcnew CspParameters();
cryptoServiceParameters->ProviderName = "Contoso";
cryptoServiceParameters->KeyContainerName = "SecurityBin1";
cryptoServiceParameters->KeyNumber = 1;
cryptoServiceParameters->ProviderType = 2;
}
// Parse specified xmlString for values to populate the CspParams
// Expected XML schema:
// <ProviderName></ProviderName>
// <KeyContainerName></KeyContainerName>
// <KeyNumber></KeyNumber>
// <ProviderType></ProviderType>
public:
virtual void FromXmlString(String^ xmlString) override
{
if (xmlString != nullptr)
{
XmlDocument^ document = gcnew XmlDocument();
document->LoadXml(xmlString);
XmlNode^ firstNode = document->FirstChild;
XmlNodeList^ nodeList;
// Assemble parameters from values in each XML element.
cryptoServiceParameters = gcnew CspParameters();
// KeyContainerName is optional.
nodeList =
document->GetElementsByTagName("KeyContainerName");
if (nodeList->Count > 0)
{
cryptoServiceParameters->KeyContainerName =
nodeList->Item(0)->InnerText;
}
// KeyNumber is optional.
nodeList = document->GetElementsByTagName("KeyNumber");
if (nodeList->Count > 0)
{
cryptoServiceParameters->KeyNumber =
Int32::Parse(nodeList->Item(0)->InnerText);
}
// ProviderName is optional.
nodeList = document->GetElementsByTagName("ProviderName");
if (nodeList->Count > 0)
{
cryptoServiceParameters->ProviderName =
nodeList->Item(0)->InnerText;
}
// ProviderType is optional.
nodeList = document->GetElementsByTagName("ProviderType");
if (nodeList->Count > 0)
{
cryptoServiceParameters->ProviderType =
Int32::Parse(nodeList->Item(0)->InnerText);
}
}
else
{
throw gcnew ArgumentNullException("xmlString");
}
}
// Create an XML string representation of the parameters in the
// current customCrypto object.
public:
virtual String^ ToXmlString(bool includePrivateParameters) override
{
String^ keyContainerName = "";
String^ keyNumber = "";
String^ providerName = "";
String^ providerType = "";
if (cryptoServiceParameters != nullptr)
{
keyContainerName =
cryptoServiceParameters->KeyContainerName;
keyNumber = cryptoServiceParameters->KeyNumber.ToString();
providerName = cryptoServiceParameters->ProviderName;
providerType =
cryptoServiceParameters->ProviderType.ToString();
}
StringBuilder^ sb = gcnew StringBuilder();
sb->Append("<CustomCryptoKeyValue>");
sb->Append("<KeyContainerName>");
sb->Append(keyContainerName);
sb->Append("</KeyContainerName>");
sb->Append("<KeyNumber>");
sb->Append(keyNumber);
sb->Append("</KeyNumber>");
sb->Append("<ProviderName>");
sb->Append(providerName);
sb->Append("</ProviderName>");
sb->Append("<ProviderType>");
sb->Append(providerType);
sb->Append("</ProviderType>");
sb->Append("</CustomCryptoKeyValue>");
return(sb->ToString());
}
// Return the name for the key exchange algorithm.
public:
property String^ KeyExchangeAlgorithm
{
virtual String^ get() override
{
return "RSA-PKCS1-KeyEx";
}
}
// Retrieves the name of the signature alogrithm.
// This example uses the SHA1 algorithm.
// Due to collision problems with SHA1, Microsoft recommends SHA256 or better.
public:
property String^ SignatureAlgorithm
{
virtual String^ get() override
{
return "http://www.w3.org/2000/09/xmldsig#rsa-sha1";
}
}
// Required member for implementing the AsymmetricAlgorithm class.
protected:
virtual ~CustomCrypto()
{
}
// Call the Create method using the CustomCrypto assembly name.
// The create function attempts to create a CustomCrypto
// object using the assembly name. This functionality requires
// modification of the machine.config file. Add the following
// section to the configuration element and modify the values
// of the cryptoClass to reflect what isinstalled
// in your machines GAC.
// <cryptoClass CustomCrypto="Contoso.CustomCrypto,
// CustomCrypto,
// Culture=neutral,
// PublicKeyToken=fdb9f9c4851028bf,
// Version=1.0.1448.27640" />
// <nameEntry name="Contoso.CustomCrypto"
// class="CustomCrypto" />
// <nameEntry name="CustomCrypto" class="CustomCrypto" />
public:
static CustomCrypto^ Create()
{
return Create("CustomCrypto");
}
// Create a CustomCrypto object by calling CrytoConfig's
// CreateFromName method and casting the type to CustomCrypto.
// The create function attempts to create a CustomCrypto object
// using the assembly name. This functionality requires
// modification of the machine.config file. Add the following
// section to the configuration element and modify the values
// of the cryptoClass to reflect what is installed
// in your machines GAC.
// <cryptoClass CustomCrypto="Contoso.CustomCrypto,
// CustomCrypto,
// Culture=neutral,
// PublicKeyToken=fdb9f9c4851028bf,
// Version=1.0.1448.27640" />
// <nameEntry name="Contoso.CustomCrypto"
// class="CustomCrypto" />
// <nameEntry name="CustomCrypto" class="CustomCrypto" />
public:
static CustomCrypto^ Create(String^ algorithmName)
{
return (CustomCrypto^)
CryptoConfig::CreateFromName(algorithmName);
}
};
}
using System;
using System.Xml;
using System.Text;
using System.Security.Cryptography;
using System.Reflection;
[assembly: AssemblyKeyFile("CustomCrypto.snk")]
[assembly: AssemblyVersion("1.0.0.0")]
[assembly: CLSCompliant(true)]
namespace Contoso
{
// Define a CustomCrypto class that inherits from the AsymmetricAlgorithm
// class.
public class CustomCrypto :
System.Security.Cryptography.AsymmetricAlgorithm
{
// Declare local member variables.
private CspParameters cspParameters;
private readonly KeySizes[] keySizes = {new KeySizes(8, 64, 8)};
// Initialize a CustomCrypto with the default key size of 8.
public CustomCrypto()
{
this.KeySize = 8;
}
// Initialize a CustomCrypto with the specified key size.
public CustomCrypto(int keySize)
{
this.KeySize = keySize;
}
// Accessor function for keySizes member variable.
public override KeySizes[] LegalKeySizes
{
get { return (KeySizes[])keySizes.Clone(); }
}
// Modify the KeySizeValue property inherited from the Asymmetric
// class. Prior to setting the value, ensure it falls within the
// range identified in the local keySizes member variable.
public override int KeySize
{
get { return KeySizeValue; }
set
{
for (int i=0; i < keySizes.Length; i++)
{
if (keySizes[i].SkipSize == 0)
{
if (keySizes[i].MinSize == value)
{
KeySizeValue = value;
return;
}
}
else
{
for (int j = keySizes[i].MinSize;
j <= keySizes[i].MaxSize;
j += keySizes[i].SkipSize)
{
if (j == value)
{
KeySizeValue = value;
return;
}
}
}
}
// If the key does not fall within the range identified
// in the keySizes member variable, throw an exception.
throw new CryptographicException("Invalid key size.");
}
}
// Initialize the parameters with default values.
public void InitializeParameters()
{
cspParameters = new CspParameters();
cspParameters.ProviderName = "Contoso";
cspParameters.KeyContainerName = "SecurityBin1";
cspParameters.KeyNumber = 1;
cspParameters.ProviderType = 2;
}
// Parse specified xmlString for values to populate the CspParams
// Expected XML schema:
// <ProviderName></ProviderName>
// <KeyContainerName></KeyContainerName>
// <KeyNumber></KeyNumber>
// <ProviderType></ProviderType>
public override void FromXmlString(string xmlString)
{
if (xmlString != null)
{
XmlDocument doc = new XmlDocument();
doc.LoadXml(xmlString);
XmlNode firstNode = doc.FirstChild;
XmlNodeList nodeList;
// Assemble parameters from values in each XML element.
cspParameters = new CspParameters();
// KeyContainerName is optional.
nodeList = doc.GetElementsByTagName("KeyContainerName");
string keyName = nodeList.Item(0).InnerText;
if (keyName != null)
{
cspParameters.KeyContainerName = keyName;
}
// KeyNumber is optional.
nodeList = doc.GetElementsByTagName("KeyNumber");
string keyNumber = nodeList.Item(0).InnerText;
if (keyNumber != null)
{
cspParameters.KeyNumber = Int32.Parse(keyNumber);
}
// ProviderName is optional.
nodeList = doc.GetElementsByTagName("ProviderName");
string providerName = nodeList.Item(0).InnerText;
if (providerName != null)
{
cspParameters.ProviderName = providerName;
}
// ProviderType is optional.
nodeList = doc.GetElementsByTagName("ProviderType");
string providerType = nodeList.Item(0).InnerText;
if (providerType != null)
{
cspParameters.ProviderType = Int32.Parse(providerType);
}
}
else
{
throw new ArgumentNullException("xmlString");
}
}
// Create an XML string representation of the parameters in the
// current customCrypto object.
public override string ToXmlString(bool includePrivateParameters)
{
string keyContainerName = "";
string keyNumber = "";
string providerName = "";
string providerType = "";
if (cspParameters != null)
{
keyContainerName = cspParameters.KeyContainerName;
keyNumber = cspParameters.KeyNumber.ToString();
providerName = cspParameters.ProviderName;
providerType = cspParameters.ProviderType.ToString();
}
StringBuilder sb = new StringBuilder();
sb.Append("<CustomCryptoKeyValue>");
sb.Append("<KeyContainerName>");
sb.Append(keyContainerName);
sb.Append("</KeyContainerName>");
sb.Append("<KeyNumber>");
sb.Append(keyNumber);
sb.Append("</KeyNumber>");
sb.Append("<ProviderName>");
sb.Append(providerName);
sb.Append("</ProviderName>");
sb.Append("<ProviderType>");
sb.Append(providerType);
sb.Append("</ProviderType>");
sb.Append("</CustomCryptoKeyValue>");
return(sb.ToString());
}
// Return the name for the key exchange algorithm.
public override string KeyExchangeAlgorithm
{
get {return "RSA-PKCS1-KeyEx";}
}
// Retrieves the name of the signature alogrithm.
// This example uses the SHA1 algorithm.
// Due to collision problems with SHA1, Microsoft recommends SHA256 or better.
public override string SignatureAlgorithm
{
get {return "http://www.w3.org/2000/09/xmldsig#rsa-sha1";}
}
// Required member for implementing the AsymmetricAlgorithm class.
protected override void Dispose(bool disposing) {}
// Call the Create method using the CustomCrypto assembly name.
// The create function attempts to create a CustomCrypto object using
// the assembly name. This functionality requires modification of the
// machine.config file. Add the following section to the configuration
// element and modify the values of the cryptoClass to reflect what is
// installed in your machines GAC.
// <cryptoClass CustomCrypto="Contoso.CustomCrypto,
// CustomCrypto,
// Culture=neutral,
// PublicKeyToken=fdb9f9c4851028bf,
// Version=1.0.1448.27640" />
// <nameEntry name="Contoso.CustomCrypto" class="CustomCrypto" />
// <nameEntry name="CustomCrypto" class="CustomCrypto" />
new static public CustomCrypto Create()
{
return Create("CustomCrypto");
}
// Create a CustomCrypto object by calling CrytoConfig's
// CreateFromName method and casting the type to CustomCrypto.
// The create function attempts to create a CustomCrypto object using
// the assembly name. This functionality requires modification of the
// machine.config file. Add the following section to the configuration
// element and modify the values of the cryptoClass to reflect what is
// installed in your machines GAC.
// <cryptoClass CustomCrypto="Contoso.CustomCrypto,
// CustomCrypto,
// Culture=neutral,
// PublicKeyToken=fdb9f9c4851028bf,
// Version=1.0.1448.27640" />
// <nameEntry name="Contoso.CustomCrypto" class="CustomCrypto" />
// <nameEntry name="CustomCrypto" class="CustomCrypto" />
new static public CustomCrypto Create(String algorithmName)
{
return (CustomCrypto) CryptoConfig.CreateFromName(algorithmName);
}
}
class CustomCryptoImpl
{
[STAThread]
static void Main(string[] args)
{
// Construct a CustomCrypto object and initialize its
// CspParameters.
CustomCrypto customCrypto = new CustomCrypto();
customCrypto.InitializeParameters();
// Display properties of the current customCrypto object.
Console.WriteLine("*** CustomCrypto created with default " +
"parameters:");
DisplayProperties(customCrypto);
// Release all the resources used by this instance of
// CustomCrytpo.
customCrypto.Clear();
customCrypto = new CustomCrypto(64);
// Create new parameters and set them by using the FromXmlString
// method.
string parameterXml = "<CustomCryptoKeyValue>";
parameterXml += "<ProviderName>Contoso</ProviderName>";
parameterXml += "<KeyContainerName>SecurityBin2";
parameterXml += "</KeyContainerName>";
parameterXml += "<KeyNumber>1</KeyNumber>";
parameterXml += "<ProviderType>2</ProviderType>";
parameterXml += "</CustomCryptoKeyValue>";
customCrypto.FromXmlString(parameterXml);
// Display the properties of a customCrypto object created with
// custom parameters.
Console.WriteLine("\n*** " +
"CustomCrypto created with custom parameters:");
DisplayProperties(customCrypto);
// Create an object by using the assembly name.
try
{
CustomCrypto myCryptoA = CustomCrypto.Create("CustomCrypto");
if (myCryptoA != null)
{
Console.Write("\n*** " +
"Successfully created CustomCrytpo from");
Console.WriteLine(" the Create method.");
DisplayProperties(myCryptoA);
}
else
{
Console.Write("Unable to create CustomCrytpo from ");
Console.WriteLine(" the Create method.");
}
}
catch (Exception ex)
{
Console.WriteLine(ex.ToString());
}
Console.WriteLine("This sample completed successfully; " +
"press Enter to exit.");
Console.ReadLine();
}
// Display the properties of the specified CustomCrypto object to the
// console.
public static void DisplayProperties(CustomCrypto customCrypto)
{
try
{
// Retrieve the class description for the customCrypto object.
string classDescription = customCrypto.ToString();
Console.WriteLine(classDescription);
Console.Write("KeyExchangeAlgorithm: ");
Console.WriteLine(customCrypto.KeyExchangeAlgorithm);
Console.Write("SignatureAlgorithm: ");
Console.WriteLine(customCrypto.SignatureAlgorithm);
Console.WriteLine("KeySize: " + customCrypto.KeySize);
Console.WriteLine("Parameters described in Xml format:");
Console.WriteLine(customCrypto.ToXmlString(true));
// Display the MinSize, MaxSize, and SkipSize properties of
// each KeySize item in the local keySizes member variable.
KeySizes[] legalKeySizes = customCrypto.LegalKeySizes;
if (legalKeySizes.Length > 0)
{
for (int i=0; i < legalKeySizes.Length; i++)
{
Console.Write("Keysize" + i + " min, max, step: ");
Console.Write(legalKeySizes[i].MinSize + ", ");
Console.Write(legalKeySizes[i].MaxSize + ", ");
Console.WriteLine(legalKeySizes[i].SkipSize + ", ");
}
}
}
catch (Exception ex)
{
Console.WriteLine("Caught unexpected exception: " +
ex.ToString());
}
}
}
}
//
// This sample produces the following output:
//
// *** CustomCrypto created with default parameters:
// Contoso.vbCustomCrypto
// KeyExchangeAlgorithm: RSA-PKCS1-KeyEx
// SignatureAlgorithm: http://www.w3.org/2000/09/xmldsig#rsa-sha1
// KeySize: 8
// Parameters described in Xml format:
// <CustomCryptoKeyValue><KeyContainerName>SecurityBin1</KeyContainerName>
// <KeyNumber>1</KeyNumber><ProviderName>Contoso</ProviderName>
// <ProviderType>2</ProviderType></CustomCryptoKeyValue>
// Keysize0 min, max, step: 8, 64, 8,
//
// *** CustomCrypto created with custom parameters:
// Contoso.vbCustomCrypto
// KeyExchangeAlgorithm: RSA-PKCS1-KeyEx
// SignatureAlgorithm: http://www.w3.org/2000/09/xmldsig#rsa-sha1
// KeySize: 64
// Parameters described in Xml format:
// <CustomCryptoKeyValue><KeyContainerName>SecurityBin2</KeyContainerName>
// <KeyNumber>1</KeyNumber><ProviderName>Contoso</ProviderName>
// <ProviderType>2</ProviderType></CustomCryptoKeyValue>
// Keysize0 min, max, step: 8, 64, 8,
// Unable to create CustomCrytpo from the Create method
// This sample completed successfully; press Exit to continue.
Imports System.Xml
Imports System.Text
Imports System.Security.Cryptography
Imports System.Reflection
<Assembly: AssemblyKeyFile("CustomCrypto.snk")>
<Assembly: AssemblyVersion("1.0.0.0")>
<Assembly: CLSCompliant(True)>
Namespace Contoso
' Define a vbCustomCrypto class that inherits from the AsymmetricAlgorithm
' class.
Class vbCustomCrypto
Inherits System.Security.Cryptography.AsymmetricAlgorithm
' Declare local member variables.
Private cspParameters As CspParameters
Private ReadOnly keySizes() As keySizes = {New keySizes(8, 64, 8)}
' Initialize a vbCustomCrypto with the default key size of 8.
Public Sub New()
Me.KeySize = 8
End Sub
' Initialize a vbCustomCrypto with the specified key size.
Public Sub New(ByVal keySize As Integer)
Me.KeySize = keySize
End Sub
' Modify the KeySizeValue property inherited from the Asymmetric
' class. Prior to setting the value, ensure it falls within the
' range identified in the local keySizes member variable.
Public Overrides Property KeySize() As Integer
Get
Return KeySizeValue
End Get
Set(ByVal Value As Integer)
For i As Int16 = 0 To keySizes.Length - 1 Step i
If (keySizes(i).SkipSize.Equals(0)) Then
If (keySizes(i).MinSize.Equals(Value)) Then
KeySizeValue = Value
Return
End If
Else
For j As Integer = keySizes(i).MinSize _
To keySizes(i).MaxSize _
Step keySizes(i).SkipSize
If (j.Equals(Value)) Then
KeySizeValue = Value
Return
End If
Next
End If
Next
' If the key does not fall within the range identified
' in the keySizes member variable, throw an exception.
Throw New CryptographicException("Invalid key size.")
End Set
End Property
' Accessor function for keySizes member variable.
public Overrides Readonly Property LegalKeySizes as KeySizes()
Get
Return keySizes
End Get
End Property
' Initialize the parameters with default values.
Public Sub InitializeParameters()
cspParameters = New CspParameters
cspParameters.ProviderName = "Contoso"
cspParameters.KeyContainerName = "SecurityBin1"
cspParameters.KeyNumber = 1
cspParameters.ProviderType = 2
End Sub
' Parse specified xmlString for values to populate the CspParams
' Expected XML schema:
' <ProviderName></ProviderName>
' <KeyContainerName></KeyContainerName>
' <KeyNumber></KeyNumber>
' <ProviderType></ProviderType>
Public Overrides Sub FromXmlString(ByVal xmlString As String)
If Not xmlString Is Nothing Then
Dim doc As New XmlDocument
doc.LoadXml(xmlString)
Dim firstNode As XmlNode = doc.FirstChild
Dim nodeList As XmlNodeList
' Assemble parameters from values in each XML element.
cspParameters = New CspParameters
' KeyContainerName is optional.
nodeList = doc.GetElementsByTagName("KeyContainerName")
Dim keyName As String = nodeList.Item(0).InnerText
If Not keyName Is Nothing Then
cspParameters.KeyContainerName = keyName
End If
' KeyNumber is optional.
nodeList = doc.GetElementsByTagName("KeyNumber")
Dim keyNumber As String = nodeList.Item(0).InnerText
If Not keyNumber Is Nothing Then
cspParameters.KeyNumber = Int32.Parse(keyNumber)
End If
' ProviderName is optional.
nodeList = doc.GetElementsByTagName("ProviderName")
Dim providerName As String = nodeList.Item(0).InnerText
If Not providerName Is Nothing Then
cspParameters.ProviderName = providerName
End If
' ProviderType is optional.
nodeList = doc.GetElementsByTagName("ProviderType")
Dim providerType As String = nodeList.Item(0).InnerText
If Not providerType Is Nothing Then
cspParameters.ProviderType = Int32.Parse(providerType)
End If
Else
Throw New ArgumentNullException("xmlString")
End If
End Sub
' Create an XML string representation of the parameters in the current
' vbCustomCrypto object.
Public Overrides Function ToXmlString( _
ByVal includePrivateParameters As Boolean) As String
Dim keyContainerName As String = ""
Dim keyNumber As String = ""
Dim providerName As String = ""
Dim providerType As String = ""
If Not cspParameters Is Nothing Then
keyContainerName = cspParameters.KeyContainerName
keyNumber = cspParameters.KeyNumber.ToString()
providerName = cspParameters.ProviderName
providerType = cspParameters.ProviderType.ToString()
End If
Dim xmlBuilder As New StringBuilder
xmlBuilder.Append("<CustomCryptoKeyValue>")
xmlBuilder.Append("<KeyContainerName>")
xmlBuilder.Append(keyContainerName)
xmlBuilder.Append("</KeyContainerName>")
xmlBuilder.Append("<KeyNumber>")
xmlBuilder.Append(keyNumber)
xmlBuilder.Append("</KeyNumber>")
xmlBuilder.Append("<ProviderName>")
xmlBuilder.Append(providerName)
xmlBuilder.Append("</ProviderName>")
xmlBuilder.Append("<ProviderType>")
xmlBuilder.Append(providerType)
xmlBuilder.Append("</ProviderType>")
xmlBuilder.Append("</CustomCryptoKeyValue>")
Return (xmlBuilder.ToString())
End Function
' Return the name for the key exchange algorithm.
Public Overrides ReadOnly Property KeyExchangeAlgorithm() As String
Get
Return "RSA-PKCS1-KeyEx"
End Get
End Property
' Retrieves the name of the signature alogrithm.
' This example uses the SHA1 algorithm.
' Due to collision problems with SHA1, Microsoft recommends SHA256 or better.
Public Overrides ReadOnly Property SignatureAlgorithm() As String
Get
Return "http://www.w3.org/2000/09/xmldsig#rsa-sha1"
End Get
End Property
' Required member for implementing the AsymmetricAlgorithm class.
Protected Overrides Sub Dispose(ByVal disposing As Boolean)
End Sub
' The create function attempts to create a vbCustomCrypto object using
' the assembly name. This functionality requires modification of the
' machine.config file. Add the following section to the configuration
' element and modify the values of the cryptoClass to reflect what is
' installed in your machines GAC.
' <cryptoClass vbCustomCrypto="Contoso.vbCustomCrypto,
' vbCustomCrypto,
' Culture=neutral,
' PublicKeyToken=fdb9f9c4851028bf,
' Version=1.0.1448.27640" />
' <nameEntry name="Contoso.vbCustomCrypto"
' class="vbCustomCrypto" />
' <nameEntry name="vbCustomCrypto" class="vbCustomCrypto" />
Public Shadows Function Create() As vbCustomCrypto
Return Create("vbCustomCrypto")
End Function
' Create a CustomCrypto object by calling CrytoConfig's
' CreateFromName method and casting the type to CustomCrypto.
' The create function attempts to create a vbCustomCrypto object using
' the assembly name. This functionality requires modification of the
' machine.config file. Add the following section to the configuration
' element and modify the values of the cryptoClass to reflect what is
' installed in your machines GAC.
' <cryptoClass vbCustomCrypto="Contoso.vbCustomCrypto,
' vbCustomCrypto,
' Culture=neutral,
' PublicKeyToken=fdb9f9c4851028bf,
' Version=1.0.1448.27640" />
' <nameEntry name="Contoso.vbCustomCrypto"
' class="vbCustomCrypto" />
' <nameEntry name="vbCustomCrypto" class="vbCustomCrypto" />
Public Shadows Function Create( _
ByVal algorithmName As String) As vbCustomCrypto
Return CType( _
CryptoConfig.CreateFromName(algorithmName), _
vbCustomCrypto)
End Function
End Class
Class Form1
Inherits System.Windows.Forms.Form
' Event handler for Run button.
Private Sub Button1_Click( _
ByVal sender As System.Object, _
ByVal e As System.EventArgs) Handles Button1.Click
tbxOutput.Cursor = Cursors.WaitCursor
tbxOutput.Text = ""
' Construct a CustomCrypto object and initialize its
' CspParameters.
Dim customCrypto As New Contoso.vbCustomCrypto
customCrypto.InitializeParameters()
' Display properties of the current vbCustomCrypto object.
WriteLine("*** CustomCrypto created with default parameters:")
DisplayProperties(customCrypto)
' Release all the resources used by this instance of CustomCrytpo.
customCrypto.Clear()
customCrypto = New Contoso.vbCustomCrypto(64)
' Create new parameters and set them by using the
' FromXmlString method.
Dim parameterXml As String = "<CustomCryptoKeyValue>"
parameterXml += "<ProviderName>Contoso</ProviderName>"
parameterXml += "<KeyContainerName>SecurityBin2"
parameterXml += "</KeyContainerName>"
parameterXml += "<KeyNumber>1</KeyNumber>"
parameterXml += "<ProviderType>2</ProviderType>"
parameterXml += "</CustomCryptoKeyValue>"
customCrypto.FromXmlString(parameterXml)
' Display the properties of a customCrypto object created with
' custom parameters.
WriteLine(vbCrLf + "*** " + _
"CustomCrypto created with custom parameters:")
DisplayProperties(customCrypto)
' Create an object by using the assembly name.
Try
Dim createdCrypto As Contoso.vbCustomCrypto
createdCrypto = customCrypto.Create("vbCustomCrypto")
If (Not createdCrypto Is Nothing) Then
Write(vbCrLf + "*** Successfully created vbCustomCrytpo ")
WriteLine("from the Create method.")
DisplayProperties(createdCrypto)
Else
Write("Unable to create CustomCrytpo from ")
WriteLine(" the Create method.")
End If
Catch ex As Exception
WriteLine(ex.ToString())
End Try
' Align interface and conclude application.
WriteLine("This sample completed successfully;" + _
" press Exit to continue.")
' Reset the cursor.
tbxOutput.Cursor = Cursors.Default
End Sub
' Display the properties of the specified CustomCrypto object to
' the output texbox.
Public Sub DisplayProperties( _
ByVal customCrypto As Contoso.vbCustomCrypto)
Try
' Retrieve the class description for the customCrypto object.
Dim classDescription As String = customCrypto.ToString()
WriteLine(classDescription)
WriteLine("KeyExchangeAlgorithm: " + _
customCrypto.KeyExchangeAlgorithm)
WriteLine("SignatureAlgorithm: " + _
customCrypto.SignatureAlgorithm)
WriteLine("KeySize: " + customCrypto.KeySize.ToString())
WriteLine("Parameters described in Xml format:")
WriteLine(customCrypto.ToXmlString(True))
' Display the MinSize, MaxSize, and SkipSize properties of
' each KeySize item in the local keySizes member variable.
Dim legalKeySizes() As KeySizes = customCrypto.LegalKeySizes
If (legalKeySizes.Length > 0) Then
For i As Integer = 0 To legalKeySizes.Length - 1 Step 1
Write("Keysize" + i.ToString() + " min, max, step: ")
Write(legalKeySizes(i).MinSize.ToString() + ", ")
Write(legalKeySizes(i).MaxSize.ToString() + ", ")
Write(legalKeySizes(i).SkipSize.ToString() + ", ")
WriteLine("")
Next
End If
Catch ex As Exception
WriteLine("Caught unexpected exception: " + ex.ToString())
End Try
End Sub
' Write the specified message and carriage return to the output
' textbox.
Private Sub WriteLine(ByVal message As String)
tbxOutput.AppendText(message + vbCrLf)
End Sub
' Write the specified message to the output textbox.
Private Sub Write(ByVal message As String)
tbxOutput.AppendText(message)
End Sub
' Event handler for Exit button.
Private Sub Button2_Click( _
ByVal sender As System.Object, _
ByVal e As System.EventArgs) Handles Button2.Click
Application.Exit()
End Sub
Public Sub New()
MyBase.New()
'This call is required by the Windows Form Designer.
InitializeComponent()
'Add any initialization after the InitializeComponent() call
End Sub
'Form overrides dispose to clean up the component list.
Protected Overloads Overrides Sub Dispose(ByVal disposing As Boolean)
If disposing Then
If Not (components Is Nothing) Then
components.Dispose()
End If
End If
MyBase.Dispose(disposing)
End Sub
'Required by the Windows Form Designer
Private components As System.ComponentModel.IContainer
'NOTE: The following procedure is required by the Windows Form
'Designer. It can be modified using the Windows Form Designer.
'Do not modify it using the code editor.
Friend WithEvents Panel2 As System.Windows.Forms.Panel
Friend WithEvents Panel1 As System.Windows.Forms.Panel
Friend WithEvents Button1 As System.Windows.Forms.Button
Friend WithEvents Button2 As System.Windows.Forms.Button
Friend WithEvents tbxOutput As System.Windows.Forms.RichTextBox
<System.Diagnostics.DebuggerStepThrough()> _
Private Sub InitializeComponent()
Me.Panel2 = New System.Windows.Forms.Panel
Me.Button1 = New System.Windows.Forms.Button
Me.Button2 = New System.Windows.Forms.Button
Me.Panel1 = New System.Windows.Forms.Panel
Me.tbxOutput = New System.Windows.Forms.RichTextBox
Me.Panel2.SuspendLayout()
Me.Panel1.SuspendLayout()
Me.SuspendLayout()
'
'Panel2
'
Me.Panel2.Controls.Add(Me.Button1)
Me.Panel2.Controls.Add(Me.Button2)
Me.Panel2.Dock = System.Windows.Forms.DockStyle.Bottom
Me.Panel2.DockPadding.All = 20
Me.Panel2.Location = New System.Drawing.Point(0, 320)
Me.Panel2.Name = "Panel2"
Me.Panel2.Size = New System.Drawing.Size(616, 64)
Me.Panel2.TabIndex = 1
'
'Button1
'
Me.Button1.Dock = System.Windows.Forms.DockStyle.Right
Me.Button1.Font = New System.Drawing.Font( _
"Microsoft Sans Serif", _
9.0!, _
System.Drawing.FontStyle.Regular, _
System.Drawing.GraphicsUnit.Point, _
CType(0, Byte))
Me.Button1.Location = New System.Drawing.Point(446, 20)
Me.Button1.Name = "Button1"
Me.Button1.Size = New System.Drawing.Size(75, 24)
Me.Button1.TabIndex = 2
Me.Button1.Text = "&Run"
'
'Button2
'
Me.Button2.Dock = System.Windows.Forms.DockStyle.Right
Me.Button2.Font = New System.Drawing.Font( _
"Microsoft Sans Serif", _
9.0!, _
System.Drawing.FontStyle.Regular, _
System.Drawing.GraphicsUnit.Point, _
CType(0, Byte))
Me.Button2.Location = New System.Drawing.Point(521, 20)
Me.Button2.Name = "Button2"
Me.Button2.Size = New System.Drawing.Size(75, 24)
Me.Button2.TabIndex = 3
Me.Button2.Text = "E&xit"
'
'Panel1
'
Me.Panel1.Controls.Add(Me.tbxOutput)
Me.Panel1.Dock = System.Windows.Forms.DockStyle.Fill
Me.Panel1.DockPadding.All = 20
Me.Panel1.Location = New System.Drawing.Point(0, 0)
Me.Panel1.Name = "Panel1"
Me.Panel1.Size = New System.Drawing.Size(616, 320)
Me.Panel1.TabIndex = 2
'
'tbxOutput
'
Me.tbxOutput.AccessibleDescription = _
"Displays output from application."
Me.tbxOutput.AccessibleName = "Output textbox."
Me.tbxOutput.Dock = System.Windows.Forms.DockStyle.Fill
Me.tbxOutput.Location = New System.Drawing.Point(20, 20)
Me.tbxOutput.Name = "tbxOutput"
Me.tbxOutput.Size = New System.Drawing.Size(576, 280)
Me.tbxOutput.TabIndex = 1
Me.tbxOutput.Text = "Click the Run button to run the application."
'
'Form1
'
Me.AutoScaleBaseSize = New System.Drawing.Size(6, 15)
Me.ClientSize = New System.Drawing.Size(616, 384)
Me.Controls.Add(Me.Panel1)
Me.Controls.Add(Me.Panel2)
Me.Name = "Form1"
Me.Text = "AsymmetricAlgorithm"
Me.Panel2.ResumeLayout(False)
Me.Panel1.ResumeLayout(False)
Me.ResumeLayout(False)
End Sub
End Class
End Namespace
'
' This sample produces the following output:
'
' *** CustomCrypto created with default parameters:
' Contoso.vbCustomCrypto
' KeyExchangeAlgorithm: RSA-PKCS1-KeyEx
' SignatureAlgorithm: http://www.w3.org/2000/09/xmldsig#rsa-sha1
' KeySize: 8
' Parameters described in Xml format:
' <CustomCryptoKeyValue><KeyContainerName>SecurityBin1</KeyContainerName>
' <KeyNumber>1</KeyNumber><ProviderName>Contoso</ProviderName>
' <ProviderType>2</ProviderType></CustomCryptoKeyValue>
' Keysize0 min, max, step: 8, 64, 8,
'
' *** CustomCrypto created with custom parameters:
' Contoso.vbCustomCrypto
' KeyExchangeAlgorithm: RSA-PKCS1-KeyEx
' SignatureAlgorithm: http://www.w3.org/2000/09/xmldsig#rsa-sha1
' KeySize: 64
' Parameters described in Xml format:
' <CustomCryptoKeyValue><KeyContainerName>SecurityBin2</KeyContainerName>
' <KeyNumber>1</KeyNumber><ProviderName>Contoso</ProviderName>
' <ProviderType>2</ProviderType></CustomCryptoKeyValue>
' Keysize0 min, max, step: 8, 64, 8,
' Unable to create CustomCrytpo from the Create method
' This sample completed successfully; press Enter to exit.
Ecco una classe aggiuntiva che illustra come usare la classe personalizzata.
#using <System.Xml.dll>
#using <System.Security.dll>
using namespace System;
using namespace System::Xml;
using namespace System::Text;
using namespace System::Security::Cryptography;
// Display the properties of the specified CustomCrypto object to the
// console.
static void DisplayProperties(Contoso::CustomCrypto^ customCryptoAlgorithm)
{
// Retrieve the class description for the customCrypto object.
String^ classDescription = customCryptoAlgorithm->ToString();
Console::WriteLine(classDescription);
Console::WriteLine("KeyExchangeAlgorithm: {0}",
customCryptoAlgorithm->KeyExchangeAlgorithm);
Console::WriteLine("SignatureAlgorithm: {0}",
customCryptoAlgorithm->SignatureAlgorithm);
Console::WriteLine("KeySize: {0}",
customCryptoAlgorithm->KeySize);
Console::WriteLine("Parameters described in Xml format:");
Console::WriteLine(customCryptoAlgorithm->ToXmlString(true));
// Display the MinSize, MaxSize, and SkipSize properties of
// each KeySize item in the local keySizes member variable.
array<KeySizes^>^ legalKeySizes = customCryptoAlgorithm->LegalKeySizes;
for (int i = 0; i < legalKeySizes->Length; i++)
{
Console::WriteLine(
"Keysize{0} min, max, step: {1}, {2}, {3}, ", i,
legalKeySizes[i]->MinSize,
legalKeySizes[i]->MaxSize,
legalKeySizes[i]->SkipSize);
}
}
[STAThread]
int main()
{
// Construct a CustomCrypto object and initialize its
// CspParameters.
Contoso::CustomCrypto^ customCryptoAlgorithm = gcnew Contoso::CustomCrypto();
customCryptoAlgorithm->InitializeParameters();
// Display properties of the current customCrypto object.
Console::WriteLine(
"*** CustomCrypto created with default parameters:");
DisplayProperties(customCryptoAlgorithm);
// Release all the resources used by this instance of
// CustomCrypto.
customCryptoAlgorithm->Clear();
customCryptoAlgorithm = gcnew Contoso::CustomCrypto(64);
// Create new parameters and set them by using the FromXmlString
// method.
String^ parameterXml = "<CustomCryptoKeyValue>" +
"<ProviderName>Contoso</ProviderName>" +
"<KeyContainerName>SecurityBin2</KeyContainerName>" +
"<KeyNumber>1</KeyNumber>" +
"<ProviderType>2</ProviderType>" +
"</CustomCryptoKeyValue>";
customCryptoAlgorithm->FromXmlString(parameterXml);
// Display the properties of a customCrypto object created with
// custom parameters.
Console::WriteLine(
"{0}*** CustomCrypto created with custom parameters:", Environment::NewLine);
DisplayProperties(customCryptoAlgorithm);
// Create an object by using the assembly name.
Contoso::CustomCrypto^ cryptoFromAssembly =
Contoso::CustomCrypto::Create("CustomCrypto");
if (cryptoFromAssembly != nullptr)
{
Console::WriteLine("{0}*** Successfully created " +
"CustomCrypto from the Create method.", Environment::NewLine);
DisplayProperties(cryptoFromAssembly);
}
else
{
Console::WriteLine("Unable to create CustomCrypto from " +
"the Create method.");
}
Console::WriteLine(
"This sample completed successfully; press Enter to exit.");
Console::ReadLine();
}
//
// This sample produces the following output:
//
// *** CustomCrypto created with default parameters:
// Contoso.vbCustomCrypto
// KeyExchangeAlgorithm: RSA-PKCS1-KeyEx
// SignatureAlgorithm: http://www.w3.org/2000/09/xmldsig#rsa-sha1
// KeySize: 8
// Parameters described in Xml format:
// <CustomCryptoKeyValue><KeyContainerName>SecurityBin1</KeyContainerName>
// <KeyNumber>1</KeyNumber><ProviderName>Contoso</ProviderName>
// <ProviderType>2</ProviderType></CustomCryptoKeyValue>
// Keysize0 min, max, step: 8, 64, 8,
//
// *** CustomCrypto created with custom parameters:
// Contoso.vbCustomCrypto
// KeyExchangeAlgorithm: RSA-PKCS1-KeyEx
// SignatureAlgorithm: http://www.w3.org/2000/09/xmldsig#rsa-sha1
// KeySize: 64
// Parameters described in Xml format:
// <CustomCryptoKeyValue><KeyContainerName>SecurityBin2</KeyContainerName>
// <KeyNumber>1</KeyNumber><ProviderName>Contoso</ProviderName>
// <ProviderType>2</ProviderType></CustomCryptoKeyValue>
// Keysize0 min, max, step: 8, 64, 8,
// Unable to create CustomCrypto from the Create method
// This sample completed successfully; press Enter to exit.
class CustomCryptoImpl
{
[STAThread]
static void Main(string[] args)
{
// Construct a CustomCrypto object and initialize its
// CspParameters.
CustomCrypto customCrypto = new CustomCrypto();
customCrypto.InitializeParameters();
// Display properties of the current customCrypto object.
Console.WriteLine("*** CustomCrypto created with default " +
"parameters:");
DisplayProperties(customCrypto);
// Release all the resources used by this instance of
// CustomCrytpo.
customCrypto.Clear();
customCrypto = new CustomCrypto(64);
// Create new parameters and set them by using the FromXmlString
// method.
string parameterXml = "<CustomCryptoKeyValue>";
parameterXml += "<ProviderName>Contoso</ProviderName>";
parameterXml += "<KeyContainerName>SecurityBin2";
parameterXml += "</KeyContainerName>";
parameterXml += "<KeyNumber>1</KeyNumber>";
parameterXml += "<ProviderType>2</ProviderType>";
parameterXml += "</CustomCryptoKeyValue>";
customCrypto.FromXmlString(parameterXml);
// Display the properties of a customCrypto object created with
// custom parameters.
Console.WriteLine("\n*** " +
"CustomCrypto created with custom parameters:");
DisplayProperties(customCrypto);
// Create an object by using the assembly name.
try
{
CustomCrypto myCryptoA = CustomCrypto.Create("CustomCrypto");
if (myCryptoA != null)
{
Console.Write("\n*** " +
"Successfully created CustomCrytpo from");
Console.WriteLine(" the Create method.");
DisplayProperties(myCryptoA);
}
else
{
Console.Write("Unable to create CustomCrytpo from ");
Console.WriteLine(" the Create method.");
}
}
catch (Exception ex)
{
Console.WriteLine(ex.ToString());
}
Console.WriteLine("This sample completed successfully; " +
"press Enter to exit.");
Console.ReadLine();
}
// Display the properties of the specified CustomCrypto object to the
// console.
public static void DisplayProperties(CustomCrypto customCrypto)
{
try
{
// Retrieve the class description for the customCrypto object.
string classDescription = customCrypto.ToString();
Console.WriteLine(classDescription);
Console.Write("KeyExchangeAlgorithm: ");
Console.WriteLine(customCrypto.KeyExchangeAlgorithm);
Console.Write("SignatureAlgorithm: ");
Console.WriteLine(customCrypto.SignatureAlgorithm);
Console.WriteLine("KeySize: " + customCrypto.KeySize);
Console.WriteLine("Parameters described in Xml format:");
Console.WriteLine(customCrypto.ToXmlString(true));
// Display the MinSize, MaxSize, and SkipSize properties of
// each KeySize item in the local keySizes member variable.
KeySizes[] legalKeySizes = customCrypto.LegalKeySizes;
if (legalKeySizes.Length > 0)
{
for (int i=0; i < legalKeySizes.Length; i++)
{
Console.Write("Keysize" + i + " min, max, step: ");
Console.Write(legalKeySizes[i].MinSize + ", ");
Console.Write(legalKeySizes[i].MaxSize + ", ");
Console.WriteLine(legalKeySizes[i].SkipSize + ", ");
}
}
}
catch (Exception ex)
{
Console.WriteLine("Caught unexpected exception: " +
ex.ToString());
}
}
}
}
//
// This sample produces the following output:
//
// *** CustomCrypto created with default parameters:
// Contoso.vbCustomCrypto
// KeyExchangeAlgorithm: RSA-PKCS1-KeyEx
// SignatureAlgorithm: http://www.w3.org/2000/09/xmldsig#rsa-sha1
// KeySize: 8
// Parameters described in Xml format:
// <CustomCryptoKeyValue><KeyContainerName>SecurityBin1</KeyContainerName>
// <KeyNumber>1</KeyNumber><ProviderName>Contoso</ProviderName>
// <ProviderType>2</ProviderType></CustomCryptoKeyValue>
// Keysize0 min, max, step: 8, 64, 8,
//
// *** CustomCrypto created with custom parameters:
// Contoso.vbCustomCrypto
// KeyExchangeAlgorithm: RSA-PKCS1-KeyEx
// SignatureAlgorithm: http://www.w3.org/2000/09/xmldsig#rsa-sha1
// KeySize: 64
// Parameters described in Xml format:
// <CustomCryptoKeyValue><KeyContainerName>SecurityBin2</KeyContainerName>
// <KeyNumber>1</KeyNumber><ProviderName>Contoso</ProviderName>
// <ProviderType>2</ProviderType></CustomCryptoKeyValue>
// Keysize0 min, max, step: 8, 64, 8,
// Unable to create CustomCrytpo from the Create method
// This sample completed successfully; press Exit to continue.
Class Form1
Inherits System.Windows.Forms.Form
' Event handler for Run button.
Private Sub Button1_Click( _
ByVal sender As System.Object, _
ByVal e As System.EventArgs) Handles Button1.Click
tbxOutput.Cursor = Cursors.WaitCursor
tbxOutput.Text = ""
' Construct a CustomCrypto object and initialize its
' CspParameters.
Dim customCrypto As New Contoso.vbCustomCrypto
customCrypto.InitializeParameters()
' Display properties of the current vbCustomCrypto object.
WriteLine("*** CustomCrypto created with default parameters:")
DisplayProperties(customCrypto)
' Release all the resources used by this instance of CustomCrytpo.
customCrypto.Clear()
customCrypto = New Contoso.vbCustomCrypto(64)
' Create new parameters and set them by using the
' FromXmlString method.
Dim parameterXml As String = "<CustomCryptoKeyValue>"
parameterXml += "<ProviderName>Contoso</ProviderName>"
parameterXml += "<KeyContainerName>SecurityBin2"
parameterXml += "</KeyContainerName>"
parameterXml += "<KeyNumber>1</KeyNumber>"
parameterXml += "<ProviderType>2</ProviderType>"
parameterXml += "</CustomCryptoKeyValue>"
customCrypto.FromXmlString(parameterXml)
' Display the properties of a customCrypto object created with
' custom parameters.
WriteLine(vbCrLf + "*** " + _
"CustomCrypto created with custom parameters:")
DisplayProperties(customCrypto)
' Create an object by using the assembly name.
Try
Dim createdCrypto As Contoso.vbCustomCrypto
createdCrypto = customCrypto.Create("vbCustomCrypto")
If (Not createdCrypto Is Nothing) Then
Write(vbCrLf + "*** Successfully created vbCustomCrytpo ")
WriteLine("from the Create method.")
DisplayProperties(createdCrypto)
Else
Write("Unable to create CustomCrytpo from ")
WriteLine(" the Create method.")
End If
Catch ex As Exception
WriteLine(ex.ToString())
End Try
' Align interface and conclude application.
WriteLine("This sample completed successfully;" + _
" press Exit to continue.")
' Reset the cursor.
tbxOutput.Cursor = Cursors.Default
End Sub
' Display the properties of the specified CustomCrypto object to
' the output texbox.
Public Sub DisplayProperties( _
ByVal customCrypto As Contoso.vbCustomCrypto)
Try
' Retrieve the class description for the customCrypto object.
Dim classDescription As String = customCrypto.ToString()
WriteLine(classDescription)
WriteLine("KeyExchangeAlgorithm: " + _
customCrypto.KeyExchangeAlgorithm)
WriteLine("SignatureAlgorithm: " + _
customCrypto.SignatureAlgorithm)
WriteLine("KeySize: " + customCrypto.KeySize.ToString())
WriteLine("Parameters described in Xml format:")
WriteLine(customCrypto.ToXmlString(True))
' Display the MinSize, MaxSize, and SkipSize properties of
' each KeySize item in the local keySizes member variable.
Dim legalKeySizes() As KeySizes = customCrypto.LegalKeySizes
If (legalKeySizes.Length > 0) Then
For i As Integer = 0 To legalKeySizes.Length - 1 Step 1
Write("Keysize" + i.ToString() + " min, max, step: ")
Write(legalKeySizes(i).MinSize.ToString() + ", ")
Write(legalKeySizes(i).MaxSize.ToString() + ", ")
Write(legalKeySizes(i).SkipSize.ToString() + ", ")
WriteLine("")
Next
End If
Catch ex As Exception
WriteLine("Caught unexpected exception: " + ex.ToString())
End Try
End Sub
' Write the specified message and carriage return to the output
' textbox.
Private Sub WriteLine(ByVal message As String)
tbxOutput.AppendText(message + vbCrLf)
End Sub
' Write the specified message to the output textbox.
Private Sub Write(ByVal message As String)
tbxOutput.AppendText(message)
End Sub
' Event handler for Exit button.
Private Sub Button2_Click( _
ByVal sender As System.Object, _
ByVal e As System.EventArgs) Handles Button2.Click
Application.Exit()
End Sub
Public Sub New()
MyBase.New()
'This call is required by the Windows Form Designer.
InitializeComponent()
'Add any initialization after the InitializeComponent() call
End Sub
'Form overrides dispose to clean up the component list.
Protected Overloads Overrides Sub Dispose(ByVal disposing As Boolean)
If disposing Then
If Not (components Is Nothing) Then
components.Dispose()
End If
End If
MyBase.Dispose(disposing)
End Sub
'Required by the Windows Form Designer
Private components As System.ComponentModel.IContainer
'NOTE: The following procedure is required by the Windows Form
'Designer. It can be modified using the Windows Form Designer.
'Do not modify it using the code editor.
Friend WithEvents Panel2 As System.Windows.Forms.Panel
Friend WithEvents Panel1 As System.Windows.Forms.Panel
Friend WithEvents Button1 As System.Windows.Forms.Button
Friend WithEvents Button2 As System.Windows.Forms.Button
Friend WithEvents tbxOutput As System.Windows.Forms.RichTextBox
<System.Diagnostics.DebuggerStepThrough()> _
Private Sub InitializeComponent()
Me.Panel2 = New System.Windows.Forms.Panel
Me.Button1 = New System.Windows.Forms.Button
Me.Button2 = New System.Windows.Forms.Button
Me.Panel1 = New System.Windows.Forms.Panel
Me.tbxOutput = New System.Windows.Forms.RichTextBox
Me.Panel2.SuspendLayout()
Me.Panel1.SuspendLayout()
Me.SuspendLayout()
'
'Panel2
'
Me.Panel2.Controls.Add(Me.Button1)
Me.Panel2.Controls.Add(Me.Button2)
Me.Panel2.Dock = System.Windows.Forms.DockStyle.Bottom
Me.Panel2.DockPadding.All = 20
Me.Panel2.Location = New System.Drawing.Point(0, 320)
Me.Panel2.Name = "Panel2"
Me.Panel2.Size = New System.Drawing.Size(616, 64)
Me.Panel2.TabIndex = 1
'
'Button1
'
Me.Button1.Dock = System.Windows.Forms.DockStyle.Right
Me.Button1.Font = New System.Drawing.Font( _
"Microsoft Sans Serif", _
9.0!, _
System.Drawing.FontStyle.Regular, _
System.Drawing.GraphicsUnit.Point, _
CType(0, Byte))
Me.Button1.Location = New System.Drawing.Point(446, 20)
Me.Button1.Name = "Button1"
Me.Button1.Size = New System.Drawing.Size(75, 24)
Me.Button1.TabIndex = 2
Me.Button1.Text = "&Run"
'
'Button2
'
Me.Button2.Dock = System.Windows.Forms.DockStyle.Right
Me.Button2.Font = New System.Drawing.Font( _
"Microsoft Sans Serif", _
9.0!, _
System.Drawing.FontStyle.Regular, _
System.Drawing.GraphicsUnit.Point, _
CType(0, Byte))
Me.Button2.Location = New System.Drawing.Point(521, 20)
Me.Button2.Name = "Button2"
Me.Button2.Size = New System.Drawing.Size(75, 24)
Me.Button2.TabIndex = 3
Me.Button2.Text = "E&xit"
'
'Panel1
'
Me.Panel1.Controls.Add(Me.tbxOutput)
Me.Panel1.Dock = System.Windows.Forms.DockStyle.Fill
Me.Panel1.DockPadding.All = 20
Me.Panel1.Location = New System.Drawing.Point(0, 0)
Me.Panel1.Name = "Panel1"
Me.Panel1.Size = New System.Drawing.Size(616, 320)
Me.Panel1.TabIndex = 2
'
'tbxOutput
'
Me.tbxOutput.AccessibleDescription = _
"Displays output from application."
Me.tbxOutput.AccessibleName = "Output textbox."
Me.tbxOutput.Dock = System.Windows.Forms.DockStyle.Fill
Me.tbxOutput.Location = New System.Drawing.Point(20, 20)
Me.tbxOutput.Name = "tbxOutput"
Me.tbxOutput.Size = New System.Drawing.Size(576, 280)
Me.tbxOutput.TabIndex = 1
Me.tbxOutput.Text = "Click the Run button to run the application."
'
'Form1
'
Me.AutoScaleBaseSize = New System.Drawing.Size(6, 15)
Me.ClientSize = New System.Drawing.Size(616, 384)
Me.Controls.Add(Me.Panel1)
Me.Controls.Add(Me.Panel2)
Me.Name = "Form1"
Me.Text = "AsymmetricAlgorithm"
Me.Panel2.ResumeLayout(False)
Me.Panel1.ResumeLayout(False)
Me.ResumeLayout(False)
End Sub
End Class
End Namespace
'
' This sample produces the following output:
'
' *** CustomCrypto created with default parameters:
' Contoso.vbCustomCrypto
' KeyExchangeAlgorithm: RSA-PKCS1-KeyEx
' SignatureAlgorithm: http://www.w3.org/2000/09/xmldsig#rsa-sha1
' KeySize: 8
' Parameters described in Xml format:
' <CustomCryptoKeyValue><KeyContainerName>SecurityBin1</KeyContainerName>
' <KeyNumber>1</KeyNumber><ProviderName>Contoso</ProviderName>
' <ProviderType>2</ProviderType></CustomCryptoKeyValue>
' Keysize0 min, max, step: 8, 64, 8,
'
' *** CustomCrypto created with custom parameters:
' Contoso.vbCustomCrypto
' KeyExchangeAlgorithm: RSA-PKCS1-KeyEx
' SignatureAlgorithm: http://www.w3.org/2000/09/xmldsig#rsa-sha1
' KeySize: 64
' Parameters described in Xml format:
' <CustomCryptoKeyValue><KeyContainerName>SecurityBin2</KeyContainerName>
' <KeyNumber>1</KeyNumber><ProviderName>Contoso</ProviderName>
' <ProviderType>2</ProviderType></CustomCryptoKeyValue>
' Keysize0 min, max, step: 8, 64, 8,
' Unable to create CustomCrytpo from the Create method
' This sample completed successfully; press Enter to exit.
Commenti
Gli algoritmi crittografici asimmetrici, noti anche come algoritmi di chiave pubblica, richiedono che sia il mittente che il ricevitore mantengano una coppia di chiavi correlate: una chiave privata e una chiave pubblica. Entrambe le chiavi sono univoche per l'entità. La chiave pubblica può essere resa disponibile a chiunque; questa chiave viene usata per la codifica dei dati inviati a un ricevitore. La chiave privata deve essere mantenuta privata dal ricevitore; questa chiave viene usata per decodificare i messaggi codificati usando la chiave pubblica del ricevitore. La RSACryptoServiceProvider classe è un'implementazione di un algoritmo a chiave pubblica. Per una discussione approfondita sulla crittografia e sugli algoritmi di chiave pubblica, vedere la sezione "Crittografia chiave pubblica" in Servizi di crittografia. Per informazioni su come usare lo strumento Nome sicuro (Sn.exe) per creare coppie chiave, vedere Procedura: Creare una coppia di chiavi Public-Private.
È possibile usare sistemi a chiave pubblica per formare firme digitali. Le firme digitali vengono usate per proteggere l'integrità dei dati. Ad esempio, per usare un sistema a chiave pubblica per firmare digitalmente un messaggio, il mittente applica prima una funzione hash al messaggio per creare un digest di messaggi. Il mittente crittografa quindi il digest del messaggio con la chiave privata del mittente per creare la firma personale del mittente. Dopo aver ricevuto il messaggio e la firma, il ricevitore decrittografa la firma usando la chiave pubblica del mittente per recuperare il digest del messaggio e esegue l'hash usando lo stesso algoritmo hash usato dal mittente. Se il digest del messaggio calcolato dal ricevitore corrisponde al digest del messaggio ricevuto dal mittente, il destinatario può presumere che il messaggio non sia stato modificato durante il transito. Si noti che chiunque può verificare una firma, perché la chiave pubblica del mittente è conoscenza comune. Questa tecnica non mantiene la segretezza del messaggio; affinché il messaggio sia segreto, deve essere crittografato anche.
.NET Framework fornisce le classi seguenti che implementano algoritmi di firma digitale: DSACryptoServiceProvider, , ECDsaRSACryptoServiceProvider(classe base) e ECDsaCng.
Lo System.Security.Cryptography spazio dei nomi fornisce classi concrete solo per RSA e DSA solo.
Per informazioni su come usare l'algoritmo RSA per crittografare e decrittografare i dati XML e creare e verificare le firme digitali XML, vedere questi articoli:
Procedura: Crittografare gli elementi XML con chiavi asimmetriche
Procedura: Decrittografare gli elementi XML con chiavi asimmetriche
Costruttori
| AsymmetricAlgorithm() |
Inizializza una nuova istanza della classe AsymmetricAlgorithm. |
Campi
| KeySizeValue |
Rappresenta la dimensione in bit del modulo della chiave usato dall'algoritmo asimmetrico. |
| LegalKeySizesValue |
Specifica le dimensioni delle chiavi supportate dall'algoritmo asimmetrico. |
Proprietà
| KeyExchangeAlgorithm |
Quando ne viene eseguito l'override in una classe derivata, ottiene il nome dell'algoritmo di scambio delle chiavi; in caso contrario, genera NotImplementedException. |
| KeySize |
Ottiene o imposta la dimensione in bit del modulo della chiave usato dall'algoritmo asimmetrico. |
| LegalKeySizes |
Ottiene le dimensioni delle chiavi supportate dall'algoritmo asimmetrico. |
| SignatureAlgorithm |
Quando ne viene eseguito l'override in una classe derivata, ottiene il nome dell'algoritmo di scambio delle chiavi; in caso contrario, genera sempre NotImplementedException. |
Metodi
| Clear() |
Rilascia tutte le risorse usate dalla classe AsymmetricAlgorithm. |
| Create() |
Obsoleti.
Obsoleti.
Crea un oggetto predefinito di crittografia usato per eseguire l'algoritmo asimmetrico. |
| Create(String) |
Obsoleti.
Crea un'istanza dell'implementazione specificata di un algoritmo asimmetrico. |
| Dispose() |
Rilascia tutte le risorse usate dall'istanza corrente della classe AsymmetricAlgorithm. |
| Dispose(Boolean) |
Rilascia le risorse non gestite usate dalla classe AsymmetricAlgorithm e facoltativamente le risorse gestite. |
| Equals(Object) |
Determina se l'oggetto specificato è uguale all'oggetto corrente. (Ereditato da Object) |
| ExportEncryptedPkcs8PrivateKey(ReadOnlySpan<Byte>, PbeParameters) |
Esporta la chiave corrente nel formato PKCS#8 EncryptedPrivateKeyInfo con una password basata su byte. |
| ExportEncryptedPkcs8PrivateKey(ReadOnlySpan<Char>, PbeParameters) |
Esporta la chiave corrente nel formato PKCS#8 EncryptedPrivateKeyInfo con una password basata su caratteri. |
| ExportEncryptedPkcs8PrivateKeyPem(ReadOnlySpan<Byte>, PbeParameters) |
Esporta la chiave corrente nel formato PKCS#8 EncryptedPrivateKeyInfo con una password basata su byte, con codifica PEM. |
| ExportEncryptedPkcs8PrivateKeyPem(ReadOnlySpan<Char>, PbeParameters) |
Esporta la chiave corrente nel formato PKCS#8 EncryptedPrivateKeyInfo con una password basata su caratteri, con codifica PEM. |
| ExportPkcs8PrivateKey() |
Esporta la chiave corrente nel formato PKCS#8 PrivateKeyInfo. |
| ExportPkcs8PrivateKeyPem() |
Esporta la chiave corrente nel formato PKCS#8 PrivateKeyInfo, con codifica PEM. |
| ExportSubjectPublicKeyInfo() |
Esporta la parte della chiave pubblica della chiave corrente nel formato X.509 SubjectPublicKeyInfo. |
| ExportSubjectPublicKeyInfoPem() |
Esporta la parte pubblica della chiave pubblica della chiave corrente nel formato X.509 SubjectPublicKeyInfo, codificato con PEM. |
| FromXmlString(String) |
Quando ne viene eseguito l'override in una classe derivata, ricostruisce un oggetto AsymmetricAlgorithm da una stringa XML; in caso contrario, genera NotImplementedException. |
| GetHashCode() |
Funge da funzione hash predefinita. (Ereditato da Object) |
| GetType() |
Ottiene l'oggetto Type dell'istanza corrente. (Ereditato da Object) |
| ImportEncryptedPkcs8PrivateKey(ReadOnlySpan<Byte>, ReadOnlySpan<Byte>, Int32) |
Quando sottoposto a override in una classe derivata, importa la coppia di chiavi pubblica/privata da una struttura PKCS#8 EncryptedPrivateKeyInfo dopo la decrittografia con una password basata su byte, sostituendo le chiavi per questo oggetto. |
| ImportEncryptedPkcs8PrivateKey(ReadOnlySpan<Char>, ReadOnlySpan<Byte>, Int32) |
Quando sottoposto a override in una classe derivata, importa la coppia di chiavi pubblica/privata da una struttura PKCS#8 EncryptedPrivateKeyInfo dopo la decrittografia con una password basata su caratteri, sostituendo le chiavi per questo oggetto. |
| ImportFromEncryptedPem(ReadOnlySpan<Char>, ReadOnlySpan<Byte>) |
Quando sottoposto a override in una classe derivata, importa una chiave con codifica PEM RFC 7468 crittografata, sostituendo le chiavi per questo oggetto. |
| ImportFromEncryptedPem(ReadOnlySpan<Char>, ReadOnlySpan<Char>) |
Quando sottoposto a override in una classe derivata, importa una chiave con codifica PEM RFC 7468 crittografata, sostituendo le chiavi per questo oggetto. |
| ImportFromPem(ReadOnlySpan<Char>) |
Quando sottoposto a override in una classe derivata, importa una chiave codificata in modo testuale RFC 7468, sostituendo le chiavi per questo oggetto. |
| ImportPkcs8PrivateKey(ReadOnlySpan<Byte>, Int32) |
Quando sottoposto a override in una classe derivata, importa la coppia di chiavi pubblica/privata da una struttura PKCS#8 PrivateKeyInfo dopo la decrittografia, sostituendo le chiavi per questo oggetto. |
| ImportSubjectPublicKeyInfo(ReadOnlySpan<Byte>, Int32) |
Quando sottoposto a override in una classe derivata, importa la chiave pubblica da una struttura X.509 SubjectPublicKeyInfo dopo la decrittografia, sostituendo le chiavi per questo oggetto. |
| MemberwiseClone() |
Crea una copia superficiale dell'oggetto Object corrente. (Ereditato da Object) |
| ToString() |
Restituisce una stringa che rappresenta l'oggetto corrente. (Ereditato da Object) |
| ToXmlString(Boolean) |
Quando ne viene eseguito l'override in una classe derivata, crea e restituisce una rappresentazione di stringa XML dell'oggetto AsymmetricAlgorithm corrente; in caso contrario, genera NotImplementedException. |
| TryExportEncryptedPkcs8PrivateKey(ReadOnlySpan<Byte>, PbeParameters, Span<Byte>, Int32) |
Quando sottoposto a override in una classe derivata, tenta di esportare la chiave corrente nel formato PKCS#8 EncryptedPrivateKeyInfo in un buffer specificato, usando una password basata su byte. |
| TryExportEncryptedPkcs8PrivateKey(ReadOnlySpan<Char>, PbeParameters, Span<Byte>, Int32) |
Quando sottoposto a override in una classe derivata, tenta di esportare la chiave corrente nel formato PKCS#8 EncryptedPrivateKeyInfo in un buffer specificato, usando una password basata su caratteri. |
| TryExportEncryptedPkcs8PrivateKeyPem(ReadOnlySpan<Byte>, PbeParameters, Span<Char>, Int32) |
Tenta di esportare la chiave corrente nel formato PKCS#8 EncryptedPrivateKeyInfo con una password basata su byte, con codifica PEM. |
| TryExportEncryptedPkcs8PrivateKeyPem(ReadOnlySpan<Char>, PbeParameters, Span<Char>, Int32) |
Esporta la chiave corrente nel formato PKCS#8 EncryptedPrivateKeyInfo con una password basata su caratteri, con codifica PEM. |
| TryExportPkcs8PrivateKey(Span<Byte>, Int32) |
Quando sottoposto a override in una classe derivata, tenta di esportare la chiave corrente nel formato PKCS#8 PrivateKeyInfo in un buffer specificato. |
| TryExportPkcs8PrivateKeyPem(Span<Char>, Int32) |
Tenta di esportare la chiave corrente nel formato PKCS#8 PrivateKeyInfo con codifica PEM in un buffer fornito. |
| TryExportSubjectPublicKeyInfo(Span<Byte>, Int32) |
Quando sottoposto a override in una classe derivata, tenta di esportare la chiave corrente nel formato X.509 SubjectPublicKeyInfo in un buffer specificato. |
| TryExportSubjectPublicKeyInfoPem(Span<Char>, Int32) |
Tenta di esportare la chiave corrente nel formato X.509 SoggettoPublicKeyInfo con codifica PEM in un buffer fornito. |
Implementazioni dell'interfaccia esplicita
| IDisposable.Dispose() |
Questa API supporta l'infrastruttura del prodotto e non è previsto che venga usata direttamente dal codice. Per una descrizione di questo membro, vedere Dispose(). |
Si applica a
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