SymmetricKeyAlgorithmProvider Class
Definition
Important
Some information relates to prerelease product that may be substantially modified before it’s released. Microsoft makes no warranties, express or implied, with respect to the information provided here.
Represents a provider of symmetric key algorithms. For more information, see Cryptographic keys.
public ref class SymmetricKeyAlgorithmProvider sealed
/// [Windows.Foundation.Metadata.ContractVersion(Windows.Foundation.UniversalApiContract, 65536)]
/// [Windows.Foundation.Metadata.MarshalingBehavior(Windows.Foundation.Metadata.MarshalingType.Agile)]
/// [Windows.Foundation.Metadata.Threading(Windows.Foundation.Metadata.ThreadingModel.Both)]
class SymmetricKeyAlgorithmProvider final
[Windows.Foundation.Metadata.ContractVersion(typeof(Windows.Foundation.UniversalApiContract), 65536)]
[Windows.Foundation.Metadata.MarshalingBehavior(Windows.Foundation.Metadata.MarshalingType.Agile)]
[Windows.Foundation.Metadata.Threading(Windows.Foundation.Metadata.ThreadingModel.Both)]
public sealed class SymmetricKeyAlgorithmProvider
Public NotInheritable Class SymmetricKeyAlgorithmProvider
- Inheritance
- Attributes
Windows requirements
Device family |
Windows 10 (introduced in 10.0.10240.0)
|
API contract |
Windows.Foundation.UniversalApiContract (introduced in v1.0)
|
Examples
using Windows.Security.Cryptography;
using Windows.Security.Cryptography.Core;
using Windows.Storage.Streams;
namespace SampleSymmetricKeyAlgorithmProvider
{
sealed partial class SymmKeyAlgProviderApp : Application
{
public SymmKeyAlgProviderApp()
{
// Initialize the application.
this.InitializeComponent();
// Initialize the encryption process.
String strMsg = "1234567812345678"; // Data to encrypt.
String strAlgName = SymmetricAlgorithmNames.AesCbc;
UInt32 keyLength = 32; // Length of the key, in bytes
BinaryStringEncoding encoding; // Binary encoding value
IBuffer iv; // Initialization vector
CryptographicKey key; // Symmetric key
// Encrypt a message.
IBuffer buffEncrypted = this.SampleCipherEncryption(
strMsg,
strAlgName,
keyLength,
out encoding,
out iv,
out key);
// Decrypt a message.
this.SampleCipherDecryption(
strAlgName,
buffEncrypted,
iv,
encoding,
key);
}
public IBuffer SampleCipherEncryption(
String strMsg,
String strAlgName,
UInt32 keyLength,
out BinaryStringEncoding encoding,
out IBuffer iv,
out CryptographicKey key)
{
// Initialize the initialization vector.
iv = null;
// Initialize the binary encoding value.
encoding = BinaryStringEncoding.Utf8;
// Create a buffer that contains the encoded message to be encrypted.
IBuffer buffMsg = CryptographicBuffer.ConvertStringToBinary(strMsg, encoding);
// Open a symmetric algorithm provider for the specified algorithm.
SymmetricKeyAlgorithmProvider objAlg = SymmetricKeyAlgorithmProvider.OpenAlgorithm(strAlgName);
// Demonstrate how to retrieve the name of the algorithm used.
String strAlgNameUsed = objAlg.AlgorithmName;
// Determine whether the message length is a multiple of the block length.
// This is not necessary for PKCS #7 algorithms which automatically pad the
// message to an appropriate length.
if (!strAlgName.Contains("PKCS7"))
{
if ((buffMsg.Length % objAlg.BlockLength) != 0)
{
throw new Exception("Message buffer length must be multiple of block length.");
}
}
// Create a symmetric key.
IBuffer keyMaterial = CryptographicBuffer.GenerateRandom(keyLength);
key = objAlg.CreateSymmetricKey(keyMaterial);
// CBC algorithms require an initialization vector. Here, a random
// number is used for the vector.
if (strAlgName.Contains("CBC"))
{
iv = CryptographicBuffer.GenerateRandom(objAlg.BlockLength);
}
// Encrypt the data and return.
IBuffer buffEncrypt = CryptographicEngine.Encrypt(key, buffMsg, iv);
return buffEncrypt;
}
public void SampleCipherDecryption(
String strAlgName,
IBuffer buffEncrypt,
IBuffer iv,
BinaryStringEncoding encoding,
CryptographicKey key)
{
// Declare a buffer to contain the decrypted data.
IBuffer buffDecrypted;
// Open an symmetric algorithm provider for the specified algorithm.
SymmetricKeyAlgorithmProvider objAlg = SymmetricKeyAlgorithmProvider.OpenAlgorithm(strAlgName);
// The input key must be securely shared between the sender of the encrypted message
// and the recipient. The initialization vector must also be shared but does not
// need to be shared in a secure manner. If the sender encodes a message string
// to a buffer, the binary encoding method must also be shared with the recipient.
buffDecrypted = CryptographicEngine.Decrypt(key, buffEncrypt, iv);
// Convert the decrypted buffer to a string (for display). If the sender created the
// original message buffer from a string, the sender must tell the recipient what
// BinaryStringEncoding value was used. Here, BinaryStringEncoding.Utf8 is used to
// convert the message to a buffer before encryption and to convert the decrypted
// buffer back to the original plaintext.
String strDecrypted = CryptographicBuffer.ConvertBinaryToString(encoding, buffDecrypted);
}
}
}
Remarks
You create a SymmetricKeyAlgorithmProvider object by calling the static OpenAlgorithm method and specifying one of the following algorithm names.
No padding:+ DES_CBC
DES_ECB
3DES_CBC
3DES_ECB
RC2_CBC
RC2_ECB
AES_CBC
AES_ECB
PKCS#7 block padding modes:+ AES_CBC_PKCS7
AES_ECB_PKCS7
DES_CBC_PKCS7
DES_ECB_PKCS7
3DES_CBC_PKCS7
3DES_ECB_PKCS7
RC2_CBC_PKCS7
RC2_ECB_PKCS7
Authenticated modes (see the EncryptedAndAuthenticatedData class):+ AES_GCM
AES_CCM
Stream Cipher:+ RC4
Properties
AlgorithmName |
Gets the name of the open symmetric algorithm. |
BlockLength |
Gets the size, in bytes, of the cipher block for the open algorithm. |
Methods
CreateSymmetricKey(IBuffer) |
Creates a symmetric key. |
OpenAlgorithm(String) |
Creates an instance of the SymmetricKeyAlgorithmProvider class and opens the specified algorithm for use. |