Values.ReEncryptResponseSourceDecrypts ciphertext and then reencrypts it entirely within KMS. You can use this operation to change the KMS key under which data is encrypted, such as when you manually rotate a KMS key or change the KMS key that protects a ciphertext. You can also use it to reencrypt ciphertext under the same KMS key, such as to change the encryption context of a ciphertext. The ReEncrypt operation can decrypt ciphertext that was encrypted by using a KMS key in an KMS operation, such as Encrypt or GenerateDataKey. It can also decrypt ciphertext that was encrypted by using the public key of an asymmetric KMS key outside of KMS. However, it cannot decrypt ciphertext produced by other libraries, such as the Amazon Web Services Encryption SDK or Amazon S3 client-side encryption. These libraries return a ciphertext format that is incompatible with KMS. When you use the ReEncrypt operation, you need to provide information for the decrypt operation and the subsequent encrypt operation. If your ciphertext was encrypted under an asymmetric KMS key, you must use the SourceKeyId parameter to identify the KMS key that encrypted the ciphertext. You must also supply the encryption algorithm that was used. This information is required to decrypt the data. If your ciphertext was encrypted under a symmetric encryption KMS key, the SourceKeyId parameter is optional. KMS can get this information from metadata that it adds to the symmetric ciphertext blob. This feature adds durability to your implementation by ensuring that authorized users can decrypt ciphertext decades after it was encrypted, even if they've lost track of the key ID. However, specifying the source KMS key is always recommended as a best practice. When you use the SourceKeyId parameter to specify a KMS key, KMS uses only the KMS key you specify. If the ciphertext was encrypted under a different KMS key, the ReEncrypt operation fails. This practice ensures that you use the KMS key that you intend. To reencrypt the data, you must use the DestinationKeyId parameter to specify the KMS key that re-encrypts the data after it is decrypted. If the destination KMS key is an asymmetric KMS key, you must also provide the encryption algorithm. The algorithm that you choose must be compatible with the KMS key. When you use an asymmetric KMS key to encrypt or reencrypt data, be sure to record the KMS key and encryption algorithm that you choose. You will be required to provide the same KMS key and encryption algorithm when you decrypt the data. If the KMS key and algorithm do not match the values used to encrypt the data, the decrypt operation fails. You are not required to supply the key ID and encryption algorithm when you decrypt with symmetric encryption KMS keys because KMS stores this information in the ciphertext blob. KMS cannot store metadata in ciphertext generated with asymmetric keys. The standard format for asymmetric key ciphertext does not include configurable fields. The KMS key that you use for this operation must be in a compatible key state. For details, see Key states of KMS keys in the Key Management Service Developer Guide. Cross-account use: Yes. The source KMS key and destination KMS key can be in different Amazon Web Services accounts. Either or both KMS keys can be in a different account than the caller. To specify a KMS key in a different account, use the key ARN or alias ARN. A short key ID is also acceptable for the source key when decrypting symmetric ciphertexts, though using a full key ARN is recommended to be more explicit about the intended KMS key. Required permissions: kms:ReEncryptFrom permission on the source KMS key (key policy) kms:ReEncryptTo permission on the destination KMS key (key policy) To permit reencryption from or to a KMS key, include the "kms:ReEncrypt*" permission in your key policy. This permission is automatically included in the key policy when you use the console to create a KMS key. But you must include it manually when you create a KMS key programmatically or when you use the PutKeyPolicy operation to set a key policy. Related operations: Decrypt Encrypt GenerateDataKey GenerateDataKeyPair Eventual consistency: The KMS API follows an eventual consistency model. For more information, see KMS eventual consistency.
type nonrec t = {ciphertextBlob : CiphertextType.t option;The reencrypted data. When you use the HTTP API or the Amazon Web Services CLI, the value is Base64-encoded. Otherwise, it is not Base64-encoded.
*)sourceKeyId : KeyIdType.t option;Unique identifier of the KMS key used to originally encrypt the data.
*)keyId : KeyIdType.t option;The Amazon Resource Name (key ARN) of the KMS key that was used to reencrypt the data.
*)sourceEncryptionAlgorithm : EncryptionAlgorithmSpec.t option;The encryption algorithm that was used to decrypt the ciphertext before it was reencrypted.
*)destinationEncryptionAlgorithm : EncryptionAlgorithmSpec.t option;The encryption algorithm that was used to reencrypt the data.
*)sourceKeyMaterialId : BackingKeyIdType.t option;The identifier of the key material used to originally encrypt the data. This field is present only when the original encryption used a symmetric encryption KMS key.
*)destinationKeyMaterialId : BackingKeyIdType.t option;The identifier of the key material used to reencrypt the data. This field is present only when data is reencrypted using a symmetric encryption KMS key.
*)}type nonrec error = [ | `DependencyTimeoutException of DependencyTimeoutException.t| `DisabledException of DisabledException.t| `DryRunOperationException of DryRunOperationException.t| `IncorrectKeyException of IncorrectKeyException.t| `InvalidCiphertextException of InvalidCiphertextException.t| `InvalidGrantTokenException of InvalidGrantTokenException.t| `InvalidKeyUsageException of InvalidKeyUsageException.t| `KMSInternalException of KMSInternalException.t| `KMSInvalidStateException of KMSInvalidStateException.t| `NotFoundException of NotFoundException.t| `Unknown_operation_error of string * string option ]val error_of_json :
string ->
Yojson.Safe.t ->
[> `DependencyTimeoutException of DependencyTimeoutException.t
| `DisabledException of DisabledException.t
| `DryRunOperationException of DryRunOperationException.t
| `IncorrectKeyException of IncorrectKeyException.t
| `InvalidCiphertextException of InvalidCiphertextException.t
| `InvalidGrantTokenException of InvalidGrantTokenException.t
| `InvalidKeyUsageException of InvalidKeyUsageException.t
| `KMSInternalException of KMSInternalException.t
| `KMSInvalidStateException of KMSInvalidStateException.t
| `KeyUnavailableException of KeyUnavailableException.t
| `NotFoundException of NotFoundException.t
| `Unknown_operation_error of string * string option ]val error_of_xml :
string ->
Awso.Xml.t ->
[> `DependencyTimeoutException of DependencyTimeoutException.t
| `DisabledException of DisabledException.t
| `DryRunOperationException of DryRunOperationException.t
| `IncorrectKeyException of IncorrectKeyException.t
| `InvalidCiphertextException of InvalidCiphertextException.t
| `InvalidGrantTokenException of InvalidGrantTokenException.t
| `InvalidKeyUsageException of InvalidKeyUsageException.t
| `KMSInternalException of KMSInternalException.t
| `KMSInvalidStateException of KMSInvalidStateException.t
| `KeyUnavailableException of KeyUnavailableException.t
| `NotFoundException of NotFoundException.t
| `Unknown_operation_error of string * string option ]val to_value :
t ->
[> `Structure of
(string
* [> `Blob of CiphertextType.t
| `Enum of string
| `String of KeyIdType.t ])
list ]