com.amazonaws.services.paymentcryptographydata

Interface AWSPaymentCryptographyDataAsync

All Superinterfaces:

AWSPaymentCryptographyData

All Known Implementing Classes:

AbstractAWSPaymentCryptographyDataAsync, AWSPaymentCryptographyDataAsyncClient

@Generated(value="com.amazonaws:aws-java-sdk-code-generator")
public interface AWSPaymentCryptographyDataAsync
extends AWSPaymentCryptographyData

Interface for accessing Payment Cryptography Data Plane asynchronously. Each asynchronous method will return a Java Future object representing the asynchronous operation; overloads which accept an AsyncHandler can be used to receive notification when an asynchronous operation completes.

Note: Do not directly implement this interface, new methods are added to it regularly. Extend from AbstractAWSPaymentCryptographyDataAsync instead.

You use the Amazon Web Services Payment Cryptography Data Plane to manage how encryption keys are used for payment-related transaction processing and associated cryptographic operations. You can encrypt, decrypt, generate, verify, and translate payment-related cryptographic operations in Amazon Web Services Payment Cryptography. For more information, see Data operations in the Amazon Web Services Payment Cryptography User Guide.

To manage your encryption keys, you use the Amazon Web Services Payment Cryptography Control Plane. You can create, import, export, share, manage, and delete keys. You can also manage Identity and Access Management (IAM) policies for keys.

Field Summary

Fields inherited from interface com.amazonaws.services.paymentcryptographydata.AWSPaymentCryptographyData

ENDPOINT_PREFIX

Method Summary

Modifier and Type	Method and Description
Future<DecryptDataResult>	decryptDataAsync(DecryptDataRequest decryptDataRequest) Decrypts ciphertext data to plaintext using a symmetric (TDES, AES), asymmetric (RSA), or derived (DUKPT or EMV) encryption key scheme.
Future<DecryptDataResult>	decryptDataAsync(DecryptDataRequest decryptDataRequest, AsyncHandler<DecryptDataRequest,DecryptDataResult> asyncHandler) Decrypts ciphertext data to plaintext using a symmetric (TDES, AES), asymmetric (RSA), or derived (DUKPT or EMV) encryption key scheme.
Future<EncryptDataResult>	encryptDataAsync(EncryptDataRequest encryptDataRequest) Encrypts plaintext data to ciphertext using a symmetric (TDES, AES), asymmetric (RSA), or derived (DUKPT or EMV) encryption key scheme.
Future<EncryptDataResult>	encryptDataAsync(EncryptDataRequest encryptDataRequest, AsyncHandler<EncryptDataRequest,EncryptDataResult> asyncHandler) Encrypts plaintext data to ciphertext using a symmetric (TDES, AES), asymmetric (RSA), or derived (DUKPT or EMV) encryption key scheme.
Future<GenerateCardValidationDataResult>	generateCardValidationDataAsync(GenerateCardValidationDataRequest generateCardValidationDataRequest) Generates card-related validation data using algorithms such as Card Verification Values (CVV/CVV2), Dynamic Card Verification Values (dCVV/dCVV2), or Card Security Codes (CSC).
Future<GenerateCardValidationDataResult>	generateCardValidationDataAsync(GenerateCardValidationDataRequest generateCardValidationDataRequest, AsyncHandler<GenerateCardValidationDataRequest,GenerateCardValidationDataResult> asyncHandler) Generates card-related validation data using algorithms such as Card Verification Values (CVV/CVV2), Dynamic Card Verification Values (dCVV/dCVV2), or Card Security Codes (CSC).
Future<GenerateMacResult>	generateMacAsync(GenerateMacRequest generateMacRequest) Generates a Message Authentication Code (MAC) cryptogram within Amazon Web Services Payment Cryptography.
Future<GenerateMacResult>	generateMacAsync(GenerateMacRequest generateMacRequest, AsyncHandler<GenerateMacRequest,GenerateMacResult> asyncHandler) Generates a Message Authentication Code (MAC) cryptogram within Amazon Web Services Payment Cryptography.
Future<GeneratePinDataResult>	generatePinDataAsync(GeneratePinDataRequest generatePinDataRequest) Generates pin-related data such as PIN, PIN Verification Value (PVV), PIN Block, and PIN Offset during new card issuance or reissuance.
Future<GeneratePinDataResult>	generatePinDataAsync(GeneratePinDataRequest generatePinDataRequest, AsyncHandler<GeneratePinDataRequest,GeneratePinDataResult> asyncHandler) Generates pin-related data such as PIN, PIN Verification Value (PVV), PIN Block, and PIN Offset during new card issuance or reissuance.
Future<ReEncryptDataResult>	reEncryptDataAsync(ReEncryptDataRequest reEncryptDataRequest) Re-encrypt ciphertext using DUKPT or Symmetric data encryption keys.
Future<ReEncryptDataResult>	reEncryptDataAsync(ReEncryptDataRequest reEncryptDataRequest, AsyncHandler<ReEncryptDataRequest,ReEncryptDataResult> asyncHandler) Re-encrypt ciphertext using DUKPT or Symmetric data encryption keys.
Future<TranslatePinDataResult>	translatePinDataAsync(TranslatePinDataRequest translatePinDataRequest) Translates encrypted PIN block from and to ISO 9564 formats 0,1,3,4.
Future<TranslatePinDataResult>	translatePinDataAsync(TranslatePinDataRequest translatePinDataRequest, AsyncHandler<TranslatePinDataRequest,TranslatePinDataResult> asyncHandler) Translates encrypted PIN block from and to ISO 9564 formats 0,1,3,4.
Future<VerifyAuthRequestCryptogramResult>	verifyAuthRequestCryptogramAsync(VerifyAuthRequestCryptogramRequest verifyAuthRequestCryptogramRequest) Verifies Authorization Request Cryptogram (ARQC) for a EMV chip payment card authorization.
Future<VerifyAuthRequestCryptogramResult>	verifyAuthRequestCryptogramAsync(VerifyAuthRequestCryptogramRequest verifyAuthRequestCryptogramRequest, AsyncHandler<VerifyAuthRequestCryptogramRequest,VerifyAuthRequestCryptogramResult> asyncHandler) Verifies Authorization Request Cryptogram (ARQC) for a EMV chip payment card authorization.
Future<VerifyCardValidationDataResult>	verifyCardValidationDataAsync(VerifyCardValidationDataRequest verifyCardValidationDataRequest) Verifies card-related validation data using algorithms such as Card Verification Values (CVV/CVV2), Dynamic Card Verification Values (dCVV/dCVV2) and Card Security Codes (CSC).
Future<VerifyCardValidationDataResult>	verifyCardValidationDataAsync(VerifyCardValidationDataRequest verifyCardValidationDataRequest, AsyncHandler<VerifyCardValidationDataRequest,VerifyCardValidationDataResult> asyncHandler) Verifies card-related validation data using algorithms such as Card Verification Values (CVV/CVV2), Dynamic Card Verification Values (dCVV/dCVV2) and Card Security Codes (CSC).
Future<VerifyMacResult>	verifyMacAsync(VerifyMacRequest verifyMacRequest) Verifies a Message Authentication Code (MAC).
Future<VerifyMacResult>	verifyMacAsync(VerifyMacRequest verifyMacRequest, AsyncHandler<VerifyMacRequest,VerifyMacResult> asyncHandler) Verifies a Message Authentication Code (MAC).
Future<VerifyPinDataResult>	verifyPinDataAsync(VerifyPinDataRequest verifyPinDataRequest) Verifies pin-related data such as PIN and PIN Offset using algorithms including VISA PVV and IBM3624.
Future<VerifyPinDataResult>	verifyPinDataAsync(VerifyPinDataRequest verifyPinDataRequest, AsyncHandler<VerifyPinDataRequest,VerifyPinDataResult> asyncHandler) Verifies pin-related data such as PIN and PIN Offset using algorithms including VISA PVV and IBM3624.

Methods inherited from interface com.amazonaws.services.paymentcryptographydata.AWSPaymentCryptographyData

decryptData, encryptData, generateCardValidationData, generateMac, generatePinData, getCachedResponseMetadata, reEncryptData, shutdown, translatePinData, verifyAuthRequestCryptogram, verifyCardValidationData, verifyMac, verifyPinData

Method Detail

decryptDataAsync

Future<DecryptDataResult> decryptDataAsync(DecryptDataRequest decryptDataRequest)

Decrypts ciphertext data to plaintext using a symmetric (TDES, AES), asymmetric (RSA), or derived (DUKPT or EMV) encryption key scheme. For more information, see Decrypt data in the Amazon Web Services Payment Cryptography User Guide.

You can use an encryption key generated within Amazon Web Services Payment Cryptography, or you can import your own encryption key by calling ImportKey. For this operation, the key must have KeyModesOfUse set to Decrypt. In asymmetric decryption, Amazon Web Services Payment Cryptography decrypts the ciphertext using the private component of the asymmetric encryption key pair. For data encryption outside of Amazon Web Services Payment Cryptography, you can export the public component of the asymmetric key pair by calling GetPublicCertificate.

For symmetric and DUKPT decryption, Amazon Web Services Payment Cryptography supports TDES and AES algorithms. For EMV decryption, Amazon Web Services Payment Cryptography supports TDES algorithms. For asymmetric decryption, Amazon Web Services Payment Cryptography supports RSA.

When you use TDES or TDES DUKPT, the ciphertext data length must be a multiple of 8 bytes. For AES or AES DUKPT, the ciphertext data length must be a multiple of 16 bytes. For RSA, it sould be equal to the key size unless padding is enabled.

For information about valid keys for this operation, see Understanding key attributes and Key types for specific data operations in the Amazon Web Services Payment Cryptography User Guide.

Cross-account use: This operation can't be used across different Amazon Web Services accounts.

Related operations:

• EncryptData

• GetPublicCertificate

• ImportKey

Parameters:

decryptDataRequest -

Returns:

A Java Future containing the result of the DecryptData operation returned by the service.

See Also:

AWS API Documentation

decryptDataAsync

Future<DecryptDataResult> decryptDataAsync(DecryptDataRequest decryptDataRequest,
                                           AsyncHandler<DecryptDataRequest,DecryptDataResult> asyncHandler)

Decrypts ciphertext data to plaintext using a symmetric (TDES, AES), asymmetric (RSA), or derived (DUKPT or EMV) encryption key scheme. For more information, see Decrypt data in the Amazon Web Services Payment Cryptography User Guide.

You can use an encryption key generated within Amazon Web Services Payment Cryptography, or you can import your own encryption key by calling ImportKey. For this operation, the key must have KeyModesOfUse set to Decrypt. In asymmetric decryption, Amazon Web Services Payment Cryptography decrypts the ciphertext using the private component of the asymmetric encryption key pair. For data encryption outside of Amazon Web Services Payment Cryptography, you can export the public component of the asymmetric key pair by calling GetPublicCertificate.

For symmetric and DUKPT decryption, Amazon Web Services Payment Cryptography supports TDES and AES algorithms. For EMV decryption, Amazon Web Services Payment Cryptography supports TDES algorithms. For asymmetric decryption, Amazon Web Services Payment Cryptography supports RSA.

When you use TDES or TDES DUKPT, the ciphertext data length must be a multiple of 8 bytes. For AES or AES DUKPT, the ciphertext data length must be a multiple of 16 bytes. For RSA, it sould be equal to the key size unless padding is enabled.

For information about valid keys for this operation, see Understanding key attributes and Key types for specific data operations in the Amazon Web Services Payment Cryptography User Guide.

Cross-account use: This operation can't be used across different Amazon Web Services accounts.

Related operations:

• EncryptData

• GetPublicCertificate

• ImportKey

Parameters:

decryptDataRequest -

asyncHandler - Asynchronous callback handler for events in the lifecycle of the request. Users can provide an implementation of the callback methods in this interface to receive notification of successful or unsuccessful completion of the operation.

Returns:

A Java Future containing the result of the DecryptData operation returned by the service.

See Also:

AWS API Documentation

encryptDataAsync

Future<EncryptDataResult> encryptDataAsync(EncryptDataRequest encryptDataRequest)

Encrypts plaintext data to ciphertext using a symmetric (TDES, AES), asymmetric (RSA), or derived (DUKPT or EMV) encryption key scheme. For more information, see Encrypt data in the Amazon Web Services Payment Cryptography User Guide.

You can generate an encryption key within Amazon Web Services Payment Cryptography by calling CreateKey. You can import your own encryption key by calling ImportKey. For this operation, the key must have KeyModesOfUse set to Encrypt. In asymmetric encryption, plaintext is encrypted using public component. You can import the public component of an asymmetric key pair created outside Amazon Web Services Payment Cryptography by calling ImportKey.

For symmetric and DUKPT encryption, Amazon Web Services Payment Cryptography supports TDES and AES algorithms. For EMV encryption, Amazon Web Services Payment Cryptography supports TDES algorithms.For asymmetric encryption, Amazon Web Services Payment Cryptography supports RSA.

When you use TDES or TDES DUKPT, the plaintext data length must be a multiple of 8 bytes. For AES or AES DUKPT, the plaintext data length must be a multiple of 16 bytes. For RSA, it sould be equal to the key size unless padding is enabled.

To encrypt using DUKPT, you must already have a BDK (Base Derivation Key) key in your account with KeyModesOfUse set to DeriveKey, or you can generate a new DUKPT key by calling CreateKey. To encrypt using EMV, you must already have an IMK (Issuer Master Key) key in your account with KeyModesOfUse set to DeriveKey.

For information about valid keys for this operation, see Understanding key attributes and Key types for specific data operations in the Amazon Web Services Payment Cryptography User Guide.

Cross-account use: This operation can't be used across different Amazon Web Services accounts.

Related operations:

• DecryptData

• GetPublicCertificate

• ImportKey

• ReEncryptData

Parameters:

encryptDataRequest -

Returns:

A Java Future containing the result of the EncryptData operation returned by the service.

See Also:

AWS API Documentation

encryptDataAsync

Future<EncryptDataResult> encryptDataAsync(EncryptDataRequest encryptDataRequest,
                                           AsyncHandler<EncryptDataRequest,EncryptDataResult> asyncHandler)

Encrypts plaintext data to ciphertext using a symmetric (TDES, AES), asymmetric (RSA), or derived (DUKPT or EMV) encryption key scheme. For more information, see Encrypt data in the Amazon Web Services Payment Cryptography User Guide.

You can generate an encryption key within Amazon Web Services Payment Cryptography by calling CreateKey. You can import your own encryption key by calling ImportKey. For this operation, the key must have KeyModesOfUse set to Encrypt. In asymmetric encryption, plaintext is encrypted using public component. You can import the public component of an asymmetric key pair created outside Amazon Web Services Payment Cryptography by calling ImportKey.

For symmetric and DUKPT encryption, Amazon Web Services Payment Cryptography supports TDES and AES algorithms. For EMV encryption, Amazon Web Services Payment Cryptography supports TDES algorithms.For asymmetric encryption, Amazon Web Services Payment Cryptography supports RSA.

When you use TDES or TDES DUKPT, the plaintext data length must be a multiple of 8 bytes. For AES or AES DUKPT, the plaintext data length must be a multiple of 16 bytes. For RSA, it sould be equal to the key size unless padding is enabled.

To encrypt using DUKPT, you must already have a BDK (Base Derivation Key) key in your account with KeyModesOfUse set to DeriveKey, or you can generate a new DUKPT key by calling CreateKey. To encrypt using EMV, you must already have an IMK (Issuer Master Key) key in your account with KeyModesOfUse set to DeriveKey.

For information about valid keys for this operation, see Understanding key attributes and Key types for specific data operations in the Amazon Web Services Payment Cryptography User Guide.

Cross-account use: This operation can't be used across different Amazon Web Services accounts.

Related operations:

• DecryptData

• GetPublicCertificate

• ImportKey

• ReEncryptData

Parameters:

encryptDataRequest -

asyncHandler - Asynchronous callback handler for events in the lifecycle of the request. Users can provide an implementation of the callback methods in this interface to receive notification of successful or unsuccessful completion of the operation.

Returns:

A Java Future containing the result of the EncryptData operation returned by the service.

See Also:

AWS API Documentation

generateCardValidationDataAsync

Future<GenerateCardValidationDataResult> generateCardValidationDataAsync(GenerateCardValidationDataRequest generateCardValidationDataRequest)

Generates card-related validation data using algorithms such as Card Verification Values (CVV/CVV2), Dynamic Card Verification Values (dCVV/dCVV2), or Card Security Codes (CSC). For more information, see Generate card data in the Amazon Web Services Payment Cryptography User Guide.

This operation generates a CVV or CSC value that is printed on a payment credit or debit card during card production. The CVV or CSC, PAN (Primary Account Number) and expiration date of the card are required to check its validity during transaction processing. To begin this operation, a CVK (Card Verification Key) encryption key is required. You can use CreateKey or ImportKey to establish a CVK within Amazon Web Services Payment Cryptography. The KeyModesOfUse should be set to Generate and Verify for a CVK encryption key.

For information about valid keys for this operation, see Understanding key attributes and Key types for specific data operations in the Amazon Web Services Payment Cryptography User Guide.

Cross-account use: This operation can't be used across different Amazon Web Services accounts.

Related operations:

• ImportKey

• VerifyCardValidationData

Parameters:

generateCardValidationDataRequest -

Returns:

A Java Future containing the result of the GenerateCardValidationData operation returned by the service.

See Also:

AWS API Documentation

generateCardValidationDataAsync

Future<GenerateCardValidationDataResult> generateCardValidationDataAsync(GenerateCardValidationDataRequest generateCardValidationDataRequest,
                                                                         AsyncHandler<GenerateCardValidationDataRequest,GenerateCardValidationDataResult> asyncHandler)

Generates card-related validation data using algorithms such as Card Verification Values (CVV/CVV2), Dynamic Card Verification Values (dCVV/dCVV2), or Card Security Codes (CSC). For more information, see Generate card data in the Amazon Web Services Payment Cryptography User Guide.

This operation generates a CVV or CSC value that is printed on a payment credit or debit card during card production. The CVV or CSC, PAN (Primary Account Number) and expiration date of the card are required to check its validity during transaction processing. To begin this operation, a CVK (Card Verification Key) encryption key is required. You can use CreateKey or ImportKey to establish a CVK within Amazon Web Services Payment Cryptography. The KeyModesOfUse should be set to Generate and Verify for a CVK encryption key.

For information about valid keys for this operation, see Understanding key attributes and Key types for specific data operations in the Amazon Web Services Payment Cryptography User Guide.

Cross-account use: This operation can't be used across different Amazon Web Services accounts.

Related operations:

• ImportKey

• VerifyCardValidationData

Parameters:

generateCardValidationDataRequest -

asyncHandler - Asynchronous callback handler for events in the lifecycle of the request. Users can provide an implementation of the callback methods in this interface to receive notification of successful or unsuccessful completion of the operation.

Returns:

A Java Future containing the result of the GenerateCardValidationData operation returned by the service.

See Also:

AWS API Documentation

generateMacAsync

Future<GenerateMacResult> generateMacAsync(GenerateMacRequest generateMacRequest)

Generates a Message Authentication Code (MAC) cryptogram within Amazon Web Services Payment Cryptography.

You can use this operation to authenticate card-related data by using known data values to generate MAC for data validation between the sending and receiving parties. This operation uses message data, a secret encryption key and MAC algorithm to generate a unique MAC value for transmission. The receiving party of the MAC must use the same message data, secret encryption key and MAC algorithm to reproduce another MAC value for comparision.

You can use this operation to generate a DUPKT, CMAC, HMAC or EMV MAC by setting generation attributes and algorithm to the associated values. The MAC generation encryption key must have valid values for KeyUsage such as TR31_M7_HMAC_KEY for HMAC generation, and they key must have KeyModesOfUse set to Generate and Verify.

For information about valid keys for this operation, see Understanding key attributes and Key types for specific data operations in the Amazon Web Services Payment Cryptography User Guide.

Cross-account use: This operation can't be used across different Amazon Web Services accounts.

Related operations:

• VerifyMac

Parameters:

generateMacRequest -

Returns:

A Java Future containing the result of the GenerateMac operation returned by the service.

See Also:

AWS API Documentation

generateMacAsync

Future<GenerateMacResult> generateMacAsync(GenerateMacRequest generateMacRequest,
                                           AsyncHandler<GenerateMacRequest,GenerateMacResult> asyncHandler)

Generates a Message Authentication Code (MAC) cryptogram within Amazon Web Services Payment Cryptography.

You can use this operation to authenticate card-related data by using known data values to generate MAC for data validation between the sending and receiving parties. This operation uses message data, a secret encryption key and MAC algorithm to generate a unique MAC value for transmission. The receiving party of the MAC must use the same message data, secret encryption key and MAC algorithm to reproduce another MAC value for comparision.

You can use this operation to generate a DUPKT, CMAC, HMAC or EMV MAC by setting generation attributes and algorithm to the associated values. The MAC generation encryption key must have valid values for KeyUsage such as TR31_M7_HMAC_KEY for HMAC generation, and they key must have KeyModesOfUse set to Generate and Verify.

For information about valid keys for this operation, see Understanding key attributes and Key types for specific data operations in the Amazon Web Services Payment Cryptography User Guide.

Cross-account use: This operation can't be used across different Amazon Web Services accounts.

Related operations:

• VerifyMac

Parameters:

generateMacRequest -

asyncHandler - Asynchronous callback handler for events in the lifecycle of the request. Users can provide an implementation of the callback methods in this interface to receive notification of successful or unsuccessful completion of the operation.

Returns:

A Java Future containing the result of the GenerateMac operation returned by the service.

See Also:

AWS API Documentation

generatePinDataAsync

Future<GeneratePinDataResult> generatePinDataAsync(GeneratePinDataRequest generatePinDataRequest)

Generates pin-related data such as PIN, PIN Verification Value (PVV), PIN Block, and PIN Offset during new card issuance or reissuance. For more information, see Generate PIN data in the Amazon Web Services Payment Cryptography User Guide.

PIN data is never transmitted in clear to or from Amazon Web Services Payment Cryptography. This operation generates PIN, PVV, or PIN Offset and then encrypts it using Pin Encryption Key (PEK) to create an EncryptedPinBlock for transmission from Amazon Web Services Payment Cryptography. This operation uses a separate Pin Verification Key (PVK) for VISA PVV generation.

For information about valid keys for this operation, see Understanding key attributes and Key types for specific data operations in the Amazon Web Services Payment Cryptography User Guide.

Cross-account use: This operation can't be used across different Amazon Web Services accounts.

Related operations:

• GenerateCardValidationData

• TranslatePinData

• VerifyPinData

Parameters:

generatePinDataRequest -

Returns:

A Java Future containing the result of the GeneratePinData operation returned by the service.

See Also:

AWS API Documentation

generatePinDataAsync

Future<GeneratePinDataResult> generatePinDataAsync(GeneratePinDataRequest generatePinDataRequest,
                                                   AsyncHandler<GeneratePinDataRequest,GeneratePinDataResult> asyncHandler)

Generates pin-related data such as PIN, PIN Verification Value (PVV), PIN Block, and PIN Offset during new card issuance or reissuance. For more information, see Generate PIN data in the Amazon Web Services Payment Cryptography User Guide.

PIN data is never transmitted in clear to or from Amazon Web Services Payment Cryptography. This operation generates PIN, PVV, or PIN Offset and then encrypts it using Pin Encryption Key (PEK) to create an EncryptedPinBlock for transmission from Amazon Web Services Payment Cryptography. This operation uses a separate Pin Verification Key (PVK) for VISA PVV generation.

For information about valid keys for this operation, see Understanding key attributes and Key types for specific data operations in the Amazon Web Services Payment Cryptography User Guide.

Cross-account use: This operation can't be used across different Amazon Web Services accounts.

Related operations:

• GenerateCardValidationData

• TranslatePinData

• VerifyPinData

Parameters:

generatePinDataRequest -

asyncHandler - Asynchronous callback handler for events in the lifecycle of the request. Users can provide an implementation of the callback methods in this interface to receive notification of successful or unsuccessful completion of the operation.

Returns:

A Java Future containing the result of the GeneratePinData operation returned by the service.

See Also:

AWS API Documentation

reEncryptDataAsync

Future<ReEncryptDataResult> reEncryptDataAsync(ReEncryptDataRequest reEncryptDataRequest)

Re-encrypt ciphertext using DUKPT or Symmetric data encryption keys.

You can either generate an encryption key within Amazon Web Services Payment Cryptography by calling CreateKey or import your own encryption key by calling ImportKey. The KeyArn for use with this operation must be in a compatible key state with KeyModesOfUse set to Encrypt.

For symmetric and DUKPT encryption, Amazon Web Services Payment Cryptography supports TDES and AES algorithms. To encrypt using DUKPT, a DUKPT key must already exist within your account with KeyModesOfUse set to DeriveKey or a new DUKPT can be generated by calling CreateKey.

For information about valid keys for this operation, see Understanding key attributes and Key types for specific data operations in the Amazon Web Services Payment Cryptography User Guide.

Cross-account use: This operation can't be used across different Amazon Web Services accounts.

Related operations:

• DecryptData

• EncryptData

• GetPublicCertificate

• ImportKey

Parameters:

reEncryptDataRequest -

Returns:

A Java Future containing the result of the ReEncryptData operation returned by the service.

See Also:

AWS API Documentation

reEncryptDataAsync

Future<ReEncryptDataResult> reEncryptDataAsync(ReEncryptDataRequest reEncryptDataRequest,
                                               AsyncHandler<ReEncryptDataRequest,ReEncryptDataResult> asyncHandler)

Re-encrypt ciphertext using DUKPT or Symmetric data encryption keys.

You can either generate an encryption key within Amazon Web Services Payment Cryptography by calling CreateKey or import your own encryption key by calling ImportKey. The KeyArn for use with this operation must be in a compatible key state with KeyModesOfUse set to Encrypt.

For symmetric and DUKPT encryption, Amazon Web Services Payment Cryptography supports TDES and AES algorithms. To encrypt using DUKPT, a DUKPT key must already exist within your account with KeyModesOfUse set to DeriveKey or a new DUKPT can be generated by calling CreateKey.

For information about valid keys for this operation, see Understanding key attributes and Key types for specific data operations in the Amazon Web Services Payment Cryptography User Guide.

Cross-account use: This operation can't be used across different Amazon Web Services accounts.

Related operations:

• DecryptData

• EncryptData

• GetPublicCertificate

• ImportKey

Parameters:

reEncryptDataRequest -

asyncHandler - Asynchronous callback handler for events in the lifecycle of the request. Users can provide an implementation of the callback methods in this interface to receive notification of successful or unsuccessful completion of the operation.

Returns:

A Java Future containing the result of the ReEncryptData operation returned by the service.

See Also:

AWS API Documentation

translatePinDataAsync

Future<TranslatePinDataResult> translatePinDataAsync(TranslatePinDataRequest translatePinDataRequest)

Translates encrypted PIN block from and to ISO 9564 formats 0,1,3,4. For more information, see Translate PIN data in the Amazon Web Services Payment Cryptography User Guide.

PIN block translation involves changing the encrytion of PIN block from one encryption key to another encryption key and changing PIN block format from one to another without PIN block data leaving Amazon Web Services Payment Cryptography. The encryption key transformation can be from PEK (Pin Encryption Key) to BDK (Base Derivation Key) for DUKPT or from BDK for DUKPT to PEK. Amazon Web Services Payment Cryptography supports TDES and AES key derivation type for DUKPT translations.

The allowed combinations of PIN block format translations are guided by PCI. It is important to note that not all encrypted PIN block formats (example, format 1) require PAN (Primary Account Number) as input. And as such, PIN block format that requires PAN (example, formats 0,3,4) cannot be translated to a format (format 1) that does not require a PAN for generation.

For information about valid keys for this operation, see Understanding key attributes and Key types for specific data operations in the Amazon Web Services Payment Cryptography User Guide.

Amazon Web Services Payment Cryptography currently supports ISO PIN block 4 translation for PIN block built using legacy PAN length. That is, PAN is the right most 12 digits excluding the check digits.

Cross-account use: This operation can't be used across different Amazon Web Services accounts.

Related operations:

• GeneratePinData

• VerifyPinData

Parameters:

translatePinDataRequest -

Returns:

A Java Future containing the result of the TranslatePinData operation returned by the service.

See Also:

AWS API Documentation

translatePinDataAsync

Future<TranslatePinDataResult> translatePinDataAsync(TranslatePinDataRequest translatePinDataRequest,
                                                     AsyncHandler<TranslatePinDataRequest,TranslatePinDataResult> asyncHandler)

Translates encrypted PIN block from and to ISO 9564 formats 0,1,3,4. For more information, see Translate PIN data in the Amazon Web Services Payment Cryptography User Guide.

PIN block translation involves changing the encrytion of PIN block from one encryption key to another encryption key and changing PIN block format from one to another without PIN block data leaving Amazon Web Services Payment Cryptography. The encryption key transformation can be from PEK (Pin Encryption Key) to BDK (Base Derivation Key) for DUKPT or from BDK for DUKPT to PEK. Amazon Web Services Payment Cryptography supports TDES and AES key derivation type for DUKPT translations.

The allowed combinations of PIN block format translations are guided by PCI. It is important to note that not all encrypted PIN block formats (example, format 1) require PAN (Primary Account Number) as input. And as such, PIN block format that requires PAN (example, formats 0,3,4) cannot be translated to a format (format 1) that does not require a PAN for generation.

For information about valid keys for this operation, see Understanding key attributes and Key types for specific data operations in the Amazon Web Services Payment Cryptography User Guide.

Amazon Web Services Payment Cryptography currently supports ISO PIN block 4 translation for PIN block built using legacy PAN length. That is, PAN is the right most 12 digits excluding the check digits.

Cross-account use: This operation can't be used across different Amazon Web Services accounts.

Related operations:

• GeneratePinData

• VerifyPinData

Parameters:

translatePinDataRequest -

asyncHandler - Asynchronous callback handler for events in the lifecycle of the request. Users can provide an implementation of the callback methods in this interface to receive notification of successful or unsuccessful completion of the operation.

Returns:

A Java Future containing the result of the TranslatePinData operation returned by the service.

See Also:

AWS API Documentation

verifyAuthRequestCryptogramAsync

Future<VerifyAuthRequestCryptogramResult> verifyAuthRequestCryptogramAsync(VerifyAuthRequestCryptogramRequest verifyAuthRequestCryptogramRequest)

Verifies Authorization Request Cryptogram (ARQC) for a EMV chip payment card authorization. For more information, see Verify auth request cryptogram in the Amazon Web Services Payment Cryptography User Guide.

ARQC generation is done outside of Amazon Web Services Payment Cryptography and is typically generated on a point of sale terminal for an EMV chip card to obtain payment authorization during transaction time. For ARQC verification, you must first import the ARQC generated outside of Amazon Web Services Payment Cryptography by calling ImportKey. This operation uses the imported ARQC and an major encryption key (DUKPT) created by calling CreateKey to either provide a boolean ARQC verification result or provide an APRC (Authorization Response Cryptogram) response using Method 1 or Method 2. The ARPC_METHOD_1 uses AuthResponseCode to generate ARPC and ARPC_METHOD_2 uses CardStatusUpdate to generate ARPC.

For information about valid keys for this operation, see Understanding key attributes and Key types for specific data operations in the Amazon Web Services Payment Cryptography User Guide.

Cross-account use: This operation can't be used across different Amazon Web Services accounts.

Related operations:

• VerifyCardValidationData

• VerifyPinData

Parameters:

verifyAuthRequestCryptogramRequest -

Returns:

A Java Future containing the result of the VerifyAuthRequestCryptogram operation returned by the service.

See Also:

AWS API Documentation

verifyAuthRequestCryptogramAsync

Future<VerifyAuthRequestCryptogramResult> verifyAuthRequestCryptogramAsync(VerifyAuthRequestCryptogramRequest verifyAuthRequestCryptogramRequest,
                                                                           AsyncHandler<VerifyAuthRequestCryptogramRequest,VerifyAuthRequestCryptogramResult> asyncHandler)

Verifies Authorization Request Cryptogram (ARQC) for a EMV chip payment card authorization. For more information, see Verify auth request cryptogram in the Amazon Web Services Payment Cryptography User Guide.

ARQC generation is done outside of Amazon Web Services Payment Cryptography and is typically generated on a point of sale terminal for an EMV chip card to obtain payment authorization during transaction time. For ARQC verification, you must first import the ARQC generated outside of Amazon Web Services Payment Cryptography by calling ImportKey. This operation uses the imported ARQC and an major encryption key (DUKPT) created by calling CreateKey to either provide a boolean ARQC verification result or provide an APRC (Authorization Response Cryptogram) response using Method 1 or Method 2. The ARPC_METHOD_1 uses AuthResponseCode to generate ARPC and ARPC_METHOD_2 uses CardStatusUpdate to generate ARPC.

For information about valid keys for this operation, see Understanding key attributes and Key types for specific data operations in the Amazon Web Services Payment Cryptography User Guide.

Cross-account use: This operation can't be used across different Amazon Web Services accounts.

Related operations:

• VerifyCardValidationData

• VerifyPinData

Parameters:

verifyAuthRequestCryptogramRequest -

asyncHandler - Asynchronous callback handler for events in the lifecycle of the request. Users can provide an implementation of the callback methods in this interface to receive notification of successful or unsuccessful completion of the operation.

Returns:

A Java Future containing the result of the VerifyAuthRequestCryptogram operation returned by the service.

See Also:

AWS API Documentation

verifyCardValidationDataAsync

Future<VerifyCardValidationDataResult> verifyCardValidationDataAsync(VerifyCardValidationDataRequest verifyCardValidationDataRequest)

Verifies card-related validation data using algorithms such as Card Verification Values (CVV/CVV2), Dynamic Card Verification Values (dCVV/dCVV2) and Card Security Codes (CSC). For more information, see Verify card data in the Amazon Web Services Payment Cryptography User Guide.

This operation validates the CVV or CSC codes that is printed on a payment credit or debit card during card payment transaction. The input values are typically provided as part of an inbound transaction to an issuer or supporting platform partner. Amazon Web Services Payment Cryptography uses CVV or CSC, PAN (Primary Account Number) and expiration date of the card to check its validity during transaction processing. In this operation, the CVK (Card Verification Key) encryption key for use with card data verification is same as the one in used for GenerateCardValidationData.

For information about valid keys for this operation, see Understanding key attributes and Key types for specific data operations in the Amazon Web Services Payment Cryptography User Guide.

Cross-account use: This operation can't be used across different Amazon Web Services accounts.

Related operations:

• GenerateCardValidationData

• VerifyAuthRequestCryptogram

• VerifyPinData

Parameters:

verifyCardValidationDataRequest -

Returns:

A Java Future containing the result of the VerifyCardValidationData operation returned by the service.

See Also:

AWS API Documentation

verifyCardValidationDataAsync

Future<VerifyCardValidationDataResult> verifyCardValidationDataAsync(VerifyCardValidationDataRequest verifyCardValidationDataRequest,
                                                                     AsyncHandler<VerifyCardValidationDataRequest,VerifyCardValidationDataResult> asyncHandler)

Verifies card-related validation data using algorithms such as Card Verification Values (CVV/CVV2), Dynamic Card Verification Values (dCVV/dCVV2) and Card Security Codes (CSC). For more information, see Verify card data in the Amazon Web Services Payment Cryptography User Guide.

This operation validates the CVV or CSC codes that is printed on a payment credit or debit card during card payment transaction. The input values are typically provided as part of an inbound transaction to an issuer or supporting platform partner. Amazon Web Services Payment Cryptography uses CVV or CSC, PAN (Primary Account Number) and expiration date of the card to check its validity during transaction processing. In this operation, the CVK (Card Verification Key) encryption key for use with card data verification is same as the one in used for GenerateCardValidationData.

For information about valid keys for this operation, see Understanding key attributes and Key types for specific data operations in the Amazon Web Services Payment Cryptography User Guide.

Cross-account use: This operation can't be used across different Amazon Web Services accounts.

Related operations:

• GenerateCardValidationData

• VerifyAuthRequestCryptogram

• VerifyPinData

Parameters:

verifyCardValidationDataRequest -

asyncHandler - Asynchronous callback handler for events in the lifecycle of the request. Users can provide an implementation of the callback methods in this interface to receive notification of successful or unsuccessful completion of the operation.

Returns:

A Java Future containing the result of the VerifyCardValidationData operation returned by the service.

See Also:

AWS API Documentation

verifyMacAsync

Future<VerifyMacResult> verifyMacAsync(VerifyMacRequest verifyMacRequest)

Verifies a Message Authentication Code (MAC).

You can use this operation to verify MAC for message data authentication such as . In this operation, you must use the same message data, secret encryption key and MAC algorithm that was used to generate MAC. You can use this operation to verify a DUPKT, CMAC, HMAC or EMV MAC by setting generation attributes and algorithm to the associated values.

For information about valid keys for this operation, see Understanding key attributes and Key types for specific data operations in the Amazon Web Services Payment Cryptography User Guide.

Cross-account use: This operation can't be used across different Amazon Web Services accounts.

Related operations:

• GenerateMac

Parameters:

verifyMacRequest -

Returns:

A Java Future containing the result of the VerifyMac operation returned by the service.

See Also:

AWS API Documentation

verifyMacAsync

Future<VerifyMacResult> verifyMacAsync(VerifyMacRequest verifyMacRequest,
                                       AsyncHandler<VerifyMacRequest,VerifyMacResult> asyncHandler)

Verifies a Message Authentication Code (MAC).

You can use this operation to verify MAC for message data authentication such as . In this operation, you must use the same message data, secret encryption key and MAC algorithm that was used to generate MAC. You can use this operation to verify a DUPKT, CMAC, HMAC or EMV MAC by setting generation attributes and algorithm to the associated values.

For information about valid keys for this operation, see Understanding key attributes and Key types for specific data operations in the Amazon Web Services Payment Cryptography User Guide.

Cross-account use: This operation can't be used across different Amazon Web Services accounts.

Related operations:

• GenerateMac

Parameters:

verifyMacRequest -

asyncHandler - Asynchronous callback handler for events in the lifecycle of the request. Users can provide an implementation of the callback methods in this interface to receive notification of successful or unsuccessful completion of the operation.

Returns:

A Java Future containing the result of the VerifyMac operation returned by the service.

See Also:

AWS API Documentation

verifyPinDataAsync

Future<VerifyPinDataResult> verifyPinDataAsync(VerifyPinDataRequest verifyPinDataRequest)

Verifies pin-related data such as PIN and PIN Offset using algorithms including VISA PVV and IBM3624. For more information, see Verify PIN data in the Amazon Web Services Payment Cryptography User Guide.

This operation verifies PIN data for user payment card. A card holder PIN data is never transmitted in clear to or from Amazon Web Services Payment Cryptography. This operation uses PIN Verification Key (PVK) for PIN or PIN Offset generation and then encrypts it using PIN Encryption Key (PEK) to create an EncryptedPinBlock for transmission from Amazon Web Services Payment Cryptography.

For information about valid keys for this operation, see Understanding key attributes and Key types for specific data operations in the Amazon Web Services Payment Cryptography User Guide.

Cross-account use: This operation can't be used across different Amazon Web Services accounts.

Related operations:

• GeneratePinData

• TranslatePinData

Parameters:

verifyPinDataRequest -

Returns:

A Java Future containing the result of the VerifyPinData operation returned by the service.

See Also:

AWS API Documentation

verifyPinDataAsync

Future<VerifyPinDataResult> verifyPinDataAsync(VerifyPinDataRequest verifyPinDataRequest,
                                               AsyncHandler<VerifyPinDataRequest,VerifyPinDataResult> asyncHandler)

Verifies pin-related data such as PIN and PIN Offset using algorithms including VISA PVV and IBM3624. For more information, see Verify PIN data in the Amazon Web Services Payment Cryptography User Guide.

This operation verifies PIN data for user payment card. A card holder PIN data is never transmitted in clear to or from Amazon Web Services Payment Cryptography. This operation uses PIN Verification Key (PVK) for PIN or PIN Offset generation and then encrypts it using PIN Encryption Key (PEK) to create an EncryptedPinBlock for transmission from Amazon Web Services Payment Cryptography.

For information about valid keys for this operation, see Understanding key attributes and Key types for specific data operations in the Amazon Web Services Payment Cryptography User Guide.

Cross-account use: This operation can't be used across different Amazon Web Services accounts.

Related operations:

• GeneratePinData

• TranslatePinData

Parameters:

verifyPinDataRequest -

asyncHandler - Asynchronous callback handler for events in the lifecycle of the request. Users can provide an implementation of the callback methods in this interface to receive notification of successful or unsuccessful completion of the operation.

Returns:

A Java Future containing the result of the VerifyPinData operation returned by the service.

See Also:

AWS API Documentation