- java.lang.Object
-
- javax.crypto.KeyAgreement
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public class KeyAgreement extends Object
This class provides the functionality of a key agreement (or key exchange) protocol.The keys involved in establishing a shared secret are created by one of the key generators (
KeyPairGenerator
orKeyGenerator
), aKeyFactory
, or as a result from an intermediate phase of the key agreement protocol.For each of the correspondents in the key exchange,
doPhase
needs to be called. For example, if this key exchange is with one other party,doPhase
needs to be called once, with thelastPhase
flag set totrue
. If this key exchange is with two other parties,doPhase
needs to be called twice, the first time setting thelastPhase
flag tofalse
, and the second time setting it totrue
. There may be any number of parties involved in a key exchange.Every implementation of the Java platform is required to support the following standard
KeyAgreement
algorithm:- DiffieHellman
- Since:
- 1.4
- See Also:
KeyGenerator
,SecretKey
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-
Constructor Summary
Constructors Modifier Constructor and Description protected
KeyAgreement(KeyAgreementSpi keyAgreeSpi, Provider provider, String algorithm)
Creates a KeyAgreement object.
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Method Summary
Methods Modifier and Type Method and Description Key
doPhase(Key key, boolean lastPhase)
Executes the next phase of this key agreement with the given key that was received from one of the other parties involved in this key agreement.byte[]
generateSecret()
Generates the shared secret and returns it in a new buffer.int
generateSecret(byte[] sharedSecret, int offset)
Generates the shared secret, and places it into the buffersharedSecret
, beginning atoffset
inclusive.SecretKey
generateSecret(String algorithm)
Creates the shared secret and returns it as aSecretKey
object of the specified algorithm.String
getAlgorithm()
Returns the algorithm name of thisKeyAgreement
object.static KeyAgreement
getInstance(String algorithm)
Returns aKeyAgreement
object that implements the specified key agreement algorithm.static KeyAgreement
getInstance(String algorithm, Provider provider)
Returns aKeyAgreement
object that implements the specified key agreement algorithm.static KeyAgreement
getInstance(String algorithm, String provider)
Returns aKeyAgreement
object that implements the specified key agreement algorithm.Provider
getProvider()
Returns the provider of thisKeyAgreement
object.void
init(Key key)
Initializes this key agreement with the given key, which is required to contain all the algorithm parameters required for this key agreement.void
init(Key key, AlgorithmParameterSpec params)
Initializes this key agreement with the given key and set of algorithm parameters.void
init(Key key, AlgorithmParameterSpec params, SecureRandom random)
Initializes this key agreement with the given key, set of algorithm parameters, and source of randomness.void
init(Key key, SecureRandom random)
Initializes this key agreement with the given key and source of randomness.
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-
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Constructor Detail
-
KeyAgreement
protected KeyAgreement(KeyAgreementSpi keyAgreeSpi, Provider provider, String algorithm)
Creates a KeyAgreement object.- Parameters:
keyAgreeSpi
- the delegateprovider
- the provideralgorithm
- the algorithm
-
-
Method Detail
-
getAlgorithm
public final String getAlgorithm()
Returns the algorithm name of thisKeyAgreement
object.This is the same name that was specified in one of the
getInstance
calls that created thisKeyAgreement
object.- Returns:
- the algorithm name of this
KeyAgreement
object.
-
getInstance
public static final KeyAgreement getInstance(String algorithm) throws NoSuchAlgorithmException
Returns aKeyAgreement
object that implements the specified key agreement algorithm.This method traverses the list of registered security Providers, starting with the most preferred Provider. A new KeyAgreement object encapsulating the KeyAgreementSpi implementation from the first Provider that supports the specified algorithm is returned.
Note that the list of registered providers may be retrieved via the
Security.getProviders()
method.- Parameters:
algorithm
- the standard name of the requested key agreement algorithm. See the KeyAgreement section in the Java Cryptography Architecture Standard Algorithm Name Documentation for information about standard algorithm names.- Returns:
- the new
KeyAgreement
object. - Throws:
NullPointerException
- if the specified algorithm is null.NoSuchAlgorithmException
- if no Provider supports a KeyAgreementSpi implementation for the specified algorithm.- See Also:
Provider
-
getInstance
public static final KeyAgreement getInstance(String algorithm, String provider) throws NoSuchAlgorithmException, NoSuchProviderException
Returns aKeyAgreement
object that implements the specified key agreement algorithm.A new KeyAgreement object encapsulating the KeyAgreementSpi implementation from the specified provider is returned. The specified provider must be registered in the security provider list.
Note that the list of registered providers may be retrieved via the
Security.getProviders()
method.- Parameters:
algorithm
- the standard name of the requested key agreement algorithm. See the KeyAgreement section in the Java Cryptography Architecture Standard Algorithm Name Documentation for information about standard algorithm names.provider
- the name of the provider.- Returns:
- the new
KeyAgreement
object. - Throws:
NullPointerException
- if the specified algorithm is null.NoSuchAlgorithmException
- if a KeyAgreementSpi implementation for the specified algorithm is not available from the specified provider.NoSuchProviderException
- if the specified provider is not registered in the security provider list.IllegalArgumentException
- if theprovider
is null or empty.- See Also:
Provider
-
getInstance
public static final KeyAgreement getInstance(String algorithm, Provider provider) throws NoSuchAlgorithmException
Returns aKeyAgreement
object that implements the specified key agreement algorithm.A new KeyAgreement object encapsulating the KeyAgreementSpi implementation from the specified Provider object is returned. Note that the specified Provider object does not have to be registered in the provider list.
- Parameters:
algorithm
- the standard name of the requested key agreement algorithm. See the KeyAgreement section in the Java Cryptography Architecture Standard Algorithm Name Documentation for information about standard algorithm names.provider
- the provider.- Returns:
- the new
KeyAgreement
object. - Throws:
NullPointerException
- if the specified algorithm is null.NoSuchAlgorithmException
- if a KeyAgreementSpi implementation for the specified algorithm is not available from the specified Provider object.IllegalArgumentException
- if theprovider
is null.- See Also:
Provider
-
getProvider
public final Provider getProvider()
Returns the provider of thisKeyAgreement
object.- Returns:
- the provider of this
KeyAgreement
object
-
init
public final void init(Key key) throws InvalidKeyException
Initializes this key agreement with the given key, which is required to contain all the algorithm parameters required for this key agreement.If this key agreement requires any random bytes, it will get them using the
implementation of the highest-priority installed provider as the source of randomness. (If none of the installed providers supply an implementation of SecureRandom, a system-provided source of randomness will be used.)SecureRandom
- Parameters:
key
- the party's private information. For example, in the case of the Diffie-Hellman key agreement, this would be the party's own Diffie-Hellman private key.- Throws:
InvalidKeyException
- if the given key is inappropriate for this key agreement, e.g., is of the wrong type or has an incompatible algorithm type.
-
init
public final void init(Key key, SecureRandom random) throws InvalidKeyException
Initializes this key agreement with the given key and source of randomness. The given key is required to contain all the algorithm parameters required for this key agreement.If the key agreement algorithm requires random bytes, it gets them from the given source of randomness,
random
. However, if the underlying algorithm implementation does not require any random bytes,random
is ignored.- Parameters:
key
- the party's private information. For example, in the case of the Diffie-Hellman key agreement, this would be the party's own Diffie-Hellman private key.random
- the source of randomness- Throws:
InvalidKeyException
- if the given key is inappropriate for this key agreement, e.g., is of the wrong type or has an incompatible algorithm type.
-
init
public final void init(Key key, AlgorithmParameterSpec params) throws InvalidKeyException, InvalidAlgorithmParameterException
Initializes this key agreement with the given key and set of algorithm parameters.If this key agreement requires any random bytes, it will get them using the
implementation of the highest-priority installed provider as the source of randomness. (If none of the installed providers supply an implementation of SecureRandom, a system-provided source of randomness will be used.)SecureRandom
- Parameters:
key
- the party's private information. For example, in the case of the Diffie-Hellman key agreement, this would be the party's own Diffie-Hellman private key.params
- the key agreement parameters- Throws:
InvalidKeyException
- if the given key is inappropriate for this key agreement, e.g., is of the wrong type or has an incompatible algorithm type.InvalidAlgorithmParameterException
- if the given parameters are inappropriate for this key agreement.
-
init
public final void init(Key key, AlgorithmParameterSpec params, SecureRandom random) throws InvalidKeyException, InvalidAlgorithmParameterException
Initializes this key agreement with the given key, set of algorithm parameters, and source of randomness.- Parameters:
key
- the party's private information. For example, in the case of the Diffie-Hellman key agreement, this would be the party's own Diffie-Hellman private key.params
- the key agreement parametersrandom
- the source of randomness- Throws:
InvalidKeyException
- if the given key is inappropriate for this key agreement, e.g., is of the wrong type or has an incompatible algorithm type.InvalidAlgorithmParameterException
- if the given parameters are inappropriate for this key agreement.
-
doPhase
public final Key doPhase(Key key, boolean lastPhase) throws InvalidKeyException, IllegalStateException
Executes the next phase of this key agreement with the given key that was received from one of the other parties involved in this key agreement.- Parameters:
key
- the key for this phase. For example, in the case of Diffie-Hellman between 2 parties, this would be the other party's Diffie-Hellman public key.lastPhase
- flag which indicates whether or not this is the last phase of this key agreement.- Returns:
- the (intermediate) key resulting from this phase, or null if this phase does not yield a key
- Throws:
InvalidKeyException
- if the given key is inappropriate for this phase.IllegalStateException
- if this key agreement has not been initialized.
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generateSecret
public final byte[] generateSecret() throws IllegalStateException
Generates the shared secret and returns it in a new buffer.This method resets this
KeyAgreement
object, so that it can be reused for further key agreements. Unless this key agreement is reinitialized with one of theinit
methods, the same private information and algorithm parameters will be used for subsequent key agreements.- Returns:
- the new buffer with the shared secret
- Throws:
IllegalStateException
- if this key agreement has not been completed yet
-
generateSecret
public final int generateSecret(byte[] sharedSecret, int offset) throws IllegalStateException, ShortBufferException
Generates the shared secret, and places it into the buffersharedSecret
, beginning atoffset
inclusive.If the
sharedSecret
buffer is too small to hold the result, aShortBufferException
is thrown. In this case, this call should be repeated with a larger output buffer.This method resets this
KeyAgreement
object, so that it can be reused for further key agreements. Unless this key agreement is reinitialized with one of theinit
methods, the same private information and algorithm parameters will be used for subsequent key agreements.- Parameters:
sharedSecret
- the buffer for the shared secretoffset
- the offset insharedSecret
where the shared secret will be stored- Returns:
- the number of bytes placed into
sharedSecret
- Throws:
IllegalStateException
- if this key agreement has not been completed yetShortBufferException
- if the given output buffer is too small to hold the secret
-
generateSecret
public final SecretKey generateSecret(String algorithm) throws IllegalStateException, NoSuchAlgorithmException, InvalidKeyException
Creates the shared secret and returns it as aSecretKey
object of the specified algorithm.This method resets this
KeyAgreement
object, so that it can be reused for further key agreements. Unless this key agreement is reinitialized with one of theinit
methods, the same private information and algorithm parameters will be used for subsequent key agreements.- Parameters:
algorithm
- the requested secret-key algorithm- Returns:
- the shared secret key
- Throws:
IllegalStateException
- if this key agreement has not been completed yetNoSuchAlgorithmException
- if the specified secret-key algorithm is not availableInvalidKeyException
- if the shared secret-key material cannot be used to generate a secret key of the specified algorithm (e.g., the key material is too short)
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Document created the 11/06/2005, last modified the 04/03/2020
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