aws_sdk_kms/operation/generate_data_key_pair/builders.rs
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// Code generated by software.amazon.smithy.rust.codegen.smithy-rs. DO NOT EDIT.
pub use crate::operation::generate_data_key_pair::_generate_data_key_pair_output::GenerateDataKeyPairOutputBuilder;
pub use crate::operation::generate_data_key_pair::_generate_data_key_pair_input::GenerateDataKeyPairInputBuilder;
impl crate::operation::generate_data_key_pair::builders::GenerateDataKeyPairInputBuilder {
/// Sends a request with this input using the given client.
pub async fn send_with(
self,
client: &crate::Client,
) -> ::std::result::Result<
crate::operation::generate_data_key_pair::GenerateDataKeyPairOutput,
::aws_smithy_runtime_api::client::result::SdkError<
crate::operation::generate_data_key_pair::GenerateDataKeyPairError,
::aws_smithy_runtime_api::client::orchestrator::HttpResponse,
>,
> {
let mut fluent_builder = client.generate_data_key_pair();
fluent_builder.inner = self;
fluent_builder.send().await
}
}
/// Fluent builder constructing a request to `GenerateDataKeyPair`.
///
/// <p>Returns a unique asymmetric data key pair for use outside of KMS. This operation returns a plaintext public key, a plaintext private key, and a copy of the private key that is encrypted under the symmetric encryption KMS key you specify. You can use the data key pair to perform asymmetric cryptography and implement digital signatures outside of KMS. The bytes in the keys are random; they are not related to the caller or to the KMS key that is used to encrypt the private key.</p>
/// <p>You can use the public key that <code>GenerateDataKeyPair</code> returns to encrypt data or verify a signature outside of KMS. Then, store the encrypted private key with the data. When you are ready to decrypt data or sign a message, you can use the <code>Decrypt</code> operation to decrypt the encrypted private key.</p>
/// <p>To generate a data key pair, you must specify a symmetric encryption KMS key to encrypt the private key in a data key pair. You cannot use an asymmetric KMS key or a KMS key in a custom key store. To get the type and origin of your KMS key, use the <code>DescribeKey</code> operation.</p>
/// <p>Use the <code>KeyPairSpec</code> parameter to choose an RSA or Elliptic Curve (ECC) data key pair. In China Regions, you can also choose an SM2 data key pair. KMS recommends that you use ECC key pairs for signing, and use RSA and SM2 key pairs for either encryption or signing, but not both. However, KMS cannot enforce any restrictions on the use of data key pairs outside of KMS.</p>
/// <p>If you are using the data key pair to encrypt data, or for any operation where you don't immediately need a private key, consider using the <code>GenerateDataKeyPairWithoutPlaintext</code> operation. <code>GenerateDataKeyPairWithoutPlaintext</code> returns a plaintext public key and an encrypted private key, but omits the plaintext private key that you need only to decrypt ciphertext or sign a message. Later, when you need to decrypt the data or sign a message, use the <code>Decrypt</code> operation to decrypt the encrypted private key in the data key pair.</p>
/// <p><code>GenerateDataKeyPair</code> returns a unique data key pair for each request. The bytes in the keys are random; they are not related to the caller or the KMS key that is used to encrypt the private key. The public key is a DER-encoded X.509 SubjectPublicKeyInfo, as specified in <a href="https://tools.ietf.org/html/rfc5280">RFC 5280</a>. The private key is a DER-encoded PKCS8 PrivateKeyInfo, as specified in <a href="https://tools.ietf.org/html/rfc5958">RFC 5958</a>.</p>
/// <p><code>GenerateDataKeyPair</code> also supports <a href="https://docs.aws.amazon.com/AWSEC2/latest/UserGuide/nitro-enclave.html">Amazon Web Services Nitro Enclaves</a>, which provide an isolated compute environment in Amazon EC2. To call <code>GenerateDataKeyPair</code> for an Amazon Web Services Nitro enclave, use the <a href="https://docs.aws.amazon.com/enclaves/latest/user/developing-applications.html#sdk">Amazon Web Services Nitro Enclaves SDK</a> or any Amazon Web Services SDK. Use the <code>Recipient</code> parameter to provide the attestation document for the enclave. <code>GenerateDataKeyPair</code> returns the public data key and a copy of the private data key encrypted under the specified KMS key, as usual. But instead of a plaintext copy of the private data key (<code>PrivateKeyPlaintext</code>), the response includes a copy of the private data key encrypted under the public key from the attestation document (<code>CiphertextForRecipient</code>). For information about the interaction between KMS and Amazon Web Services Nitro Enclaves, see <a href="https://docs.aws.amazon.com/kms/latest/developerguide/services-nitro-enclaves.html">How Amazon Web Services Nitro Enclaves uses KMS</a> in the <i>Key Management Service Developer Guide</i>..</p>
/// <p>You can use an optional encryption context to add additional security to the encryption operation. If you specify an <code>EncryptionContext</code>, you must specify the same encryption context (a case-sensitive exact match) when decrypting the encrypted data key. Otherwise, the request to decrypt fails with an <code>InvalidCiphertextException</code>. For more information, see <a href="https://docs.aws.amazon.com/kms/latest/developerguide/concepts.html#encrypt_context">Encryption Context</a> in the <i>Key Management Service Developer Guide</i>.</p>
/// <p>The KMS key that you use for this operation must be in a compatible key state. For details, see <a href="https://docs.aws.amazon.com/kms/latest/developerguide/key-state.html">Key states of KMS keys</a> in the <i>Key Management Service Developer Guide</i>.</p>
/// <p><b>Cross-account use</b>: Yes. To perform this operation with a KMS key in a different Amazon Web Services account, specify the key ARN or alias ARN in the value of the <code>KeyId</code> parameter.</p>
/// <p><b>Required permissions</b>: <a href="https://docs.aws.amazon.com/kms/latest/developerguide/kms-api-permissions-reference.html">kms:GenerateDataKeyPair</a> (key policy)</p>
/// <p><b>Related operations:</b></p>
/// <ul>
/// <li>
/// <p><code>Decrypt</code></p></li>
/// <li>
/// <p><code>Encrypt</code></p></li>
/// <li>
/// <p><code>GenerateDataKey</code></p></li>
/// <li>
/// <p><code>GenerateDataKeyPairWithoutPlaintext</code></p></li>
/// <li>
/// <p><code>GenerateDataKeyWithoutPlaintext</code></p></li>
/// </ul>
/// <p><b>Eventual consistency</b>: The KMS API follows an eventual consistency model. For more information, see <a href="https://docs.aws.amazon.com/kms/latest/developerguide/programming-eventual-consistency.html">KMS eventual consistency</a>.</p>
#[derive(::std::clone::Clone, ::std::fmt::Debug)]
pub struct GenerateDataKeyPairFluentBuilder {
handle: ::std::sync::Arc<crate::client::Handle>,
inner: crate::operation::generate_data_key_pair::builders::GenerateDataKeyPairInputBuilder,
config_override: ::std::option::Option<crate::config::Builder>,
}
impl
crate::client::customize::internal::CustomizableSend<
crate::operation::generate_data_key_pair::GenerateDataKeyPairOutput,
crate::operation::generate_data_key_pair::GenerateDataKeyPairError,
> for GenerateDataKeyPairFluentBuilder
{
fn send(
self,
config_override: crate::config::Builder,
) -> crate::client::customize::internal::BoxFuture<
crate::client::customize::internal::SendResult<
crate::operation::generate_data_key_pair::GenerateDataKeyPairOutput,
crate::operation::generate_data_key_pair::GenerateDataKeyPairError,
>,
> {
::std::boxed::Box::pin(async move { self.config_override(config_override).send().await })
}
}
impl GenerateDataKeyPairFluentBuilder {
/// Creates a new `GenerateDataKeyPairFluentBuilder`.
pub(crate) fn new(handle: ::std::sync::Arc<crate::client::Handle>) -> Self {
Self {
handle,
inner: ::std::default::Default::default(),
config_override: ::std::option::Option::None,
}
}
/// Access the GenerateDataKeyPair as a reference.
pub fn as_input(&self) -> &crate::operation::generate_data_key_pair::builders::GenerateDataKeyPairInputBuilder {
&self.inner
}
/// Sends the request and returns the response.
///
/// If an error occurs, an `SdkError` will be returned with additional details that
/// can be matched against.
///
/// By default, any retryable failures will be retried twice. Retry behavior
/// is configurable with the [RetryConfig](aws_smithy_types::retry::RetryConfig), which can be
/// set when configuring the client.
pub async fn send(
self,
) -> ::std::result::Result<
crate::operation::generate_data_key_pair::GenerateDataKeyPairOutput,
::aws_smithy_runtime_api::client::result::SdkError<
crate::operation::generate_data_key_pair::GenerateDataKeyPairError,
::aws_smithy_runtime_api::client::orchestrator::HttpResponse,
>,
> {
let input = self
.inner
.build()
.map_err(::aws_smithy_runtime_api::client::result::SdkError::construction_failure)?;
let runtime_plugins = crate::operation::generate_data_key_pair::GenerateDataKeyPair::operation_runtime_plugins(
self.handle.runtime_plugins.clone(),
&self.handle.conf,
self.config_override,
);
crate::operation::generate_data_key_pair::GenerateDataKeyPair::orchestrate(&runtime_plugins, input).await
}
/// Consumes this builder, creating a customizable operation that can be modified before being sent.
pub fn customize(
self,
) -> crate::client::customize::CustomizableOperation<
crate::operation::generate_data_key_pair::GenerateDataKeyPairOutput,
crate::operation::generate_data_key_pair::GenerateDataKeyPairError,
Self,
> {
crate::client::customize::CustomizableOperation::new(self)
}
pub(crate) fn config_override(mut self, config_override: impl ::std::convert::Into<crate::config::Builder>) -> Self {
self.set_config_override(::std::option::Option::Some(config_override.into()));
self
}
pub(crate) fn set_config_override(&mut self, config_override: ::std::option::Option<crate::config::Builder>) -> &mut Self {
self.config_override = config_override;
self
}
///
/// Adds a key-value pair to `EncryptionContext`.
///
/// To override the contents of this collection use [`set_encryption_context`](Self::set_encryption_context).
///
/// <p>Specifies the encryption context that will be used when encrypting the private key in the data key pair.</p><important>
/// <p>Do not include confidential or sensitive information in this field. This field may be displayed in plaintext in CloudTrail logs and other output.</p>
/// </important>
/// <p>An <i>encryption context</i> is a collection of non-secret key-value pairs that represent additional authenticated data. When you use an encryption context to encrypt data, you must specify the same (an exact case-sensitive match) encryption context to decrypt the data. An encryption context is supported only on operations with symmetric encryption KMS keys. On operations with symmetric encryption KMS keys, an encryption context is optional, but it is strongly recommended.</p>
/// <p>For more information, see <a href="https://docs.aws.amazon.com/kms/latest/developerguide/concepts.html#encrypt_context">Encryption context</a> in the <i>Key Management Service Developer Guide</i>.</p>
pub fn encryption_context(
mut self,
k: impl ::std::convert::Into<::std::string::String>,
v: impl ::std::convert::Into<::std::string::String>,
) -> Self {
self.inner = self.inner.encryption_context(k.into(), v.into());
self
}
/// <p>Specifies the encryption context that will be used when encrypting the private key in the data key pair.</p><important>
/// <p>Do not include confidential or sensitive information in this field. This field may be displayed in plaintext in CloudTrail logs and other output.</p>
/// </important>
/// <p>An <i>encryption context</i> is a collection of non-secret key-value pairs that represent additional authenticated data. When you use an encryption context to encrypt data, you must specify the same (an exact case-sensitive match) encryption context to decrypt the data. An encryption context is supported only on operations with symmetric encryption KMS keys. On operations with symmetric encryption KMS keys, an encryption context is optional, but it is strongly recommended.</p>
/// <p>For more information, see <a href="https://docs.aws.amazon.com/kms/latest/developerguide/concepts.html#encrypt_context">Encryption context</a> in the <i>Key Management Service Developer Guide</i>.</p>
pub fn set_encryption_context(
mut self,
input: ::std::option::Option<::std::collections::HashMap<::std::string::String, ::std::string::String>>,
) -> Self {
self.inner = self.inner.set_encryption_context(input);
self
}
/// <p>Specifies the encryption context that will be used when encrypting the private key in the data key pair.</p><important>
/// <p>Do not include confidential or sensitive information in this field. This field may be displayed in plaintext in CloudTrail logs and other output.</p>
/// </important>
/// <p>An <i>encryption context</i> is a collection of non-secret key-value pairs that represent additional authenticated data. When you use an encryption context to encrypt data, you must specify the same (an exact case-sensitive match) encryption context to decrypt the data. An encryption context is supported only on operations with symmetric encryption KMS keys. On operations with symmetric encryption KMS keys, an encryption context is optional, but it is strongly recommended.</p>
/// <p>For more information, see <a href="https://docs.aws.amazon.com/kms/latest/developerguide/concepts.html#encrypt_context">Encryption context</a> in the <i>Key Management Service Developer Guide</i>.</p>
pub fn get_encryption_context(&self) -> &::std::option::Option<::std::collections::HashMap<::std::string::String, ::std::string::String>> {
self.inner.get_encryption_context()
}
/// <p>Specifies the symmetric encryption KMS key that encrypts the private key in the data key pair. You cannot specify an asymmetric KMS key or a KMS key in a custom key store. To get the type and origin of your KMS key, use the <code>DescribeKey</code> operation.</p>
/// <p>To specify a KMS key, use its key ID, key ARN, alias name, or alias ARN. When using an alias name, prefix it with <code>"alias/"</code>. To specify a KMS key in a different Amazon Web Services account, you must use the key ARN or alias ARN.</p>
/// <p>For example:</p>
/// <ul>
/// <li>
/// <p>Key ID: <code>1234abcd-12ab-34cd-56ef-1234567890ab</code></p></li>
/// <li>
/// <p>Key ARN: <code>arn:aws:kms:us-east-2:111122223333:key/1234abcd-12ab-34cd-56ef-1234567890ab</code></p></li>
/// <li>
/// <p>Alias name: <code>alias/ExampleAlias</code></p></li>
/// <li>
/// <p>Alias ARN: <code>arn:aws:kms:us-east-2:111122223333:alias/ExampleAlias</code></p></li>
/// </ul>
/// <p>To get the key ID and key ARN for a KMS key, use <code>ListKeys</code> or <code>DescribeKey</code>. To get the alias name and alias ARN, use <code>ListAliases</code>.</p>
pub fn key_id(mut self, input: impl ::std::convert::Into<::std::string::String>) -> Self {
self.inner = self.inner.key_id(input.into());
self
}
/// <p>Specifies the symmetric encryption KMS key that encrypts the private key in the data key pair. You cannot specify an asymmetric KMS key or a KMS key in a custom key store. To get the type and origin of your KMS key, use the <code>DescribeKey</code> operation.</p>
/// <p>To specify a KMS key, use its key ID, key ARN, alias name, or alias ARN. When using an alias name, prefix it with <code>"alias/"</code>. To specify a KMS key in a different Amazon Web Services account, you must use the key ARN or alias ARN.</p>
/// <p>For example:</p>
/// <ul>
/// <li>
/// <p>Key ID: <code>1234abcd-12ab-34cd-56ef-1234567890ab</code></p></li>
/// <li>
/// <p>Key ARN: <code>arn:aws:kms:us-east-2:111122223333:key/1234abcd-12ab-34cd-56ef-1234567890ab</code></p></li>
/// <li>
/// <p>Alias name: <code>alias/ExampleAlias</code></p></li>
/// <li>
/// <p>Alias ARN: <code>arn:aws:kms:us-east-2:111122223333:alias/ExampleAlias</code></p></li>
/// </ul>
/// <p>To get the key ID and key ARN for a KMS key, use <code>ListKeys</code> or <code>DescribeKey</code>. To get the alias name and alias ARN, use <code>ListAliases</code>.</p>
pub fn set_key_id(mut self, input: ::std::option::Option<::std::string::String>) -> Self {
self.inner = self.inner.set_key_id(input);
self
}
/// <p>Specifies the symmetric encryption KMS key that encrypts the private key in the data key pair. You cannot specify an asymmetric KMS key or a KMS key in a custom key store. To get the type and origin of your KMS key, use the <code>DescribeKey</code> operation.</p>
/// <p>To specify a KMS key, use its key ID, key ARN, alias name, or alias ARN. When using an alias name, prefix it with <code>"alias/"</code>. To specify a KMS key in a different Amazon Web Services account, you must use the key ARN or alias ARN.</p>
/// <p>For example:</p>
/// <ul>
/// <li>
/// <p>Key ID: <code>1234abcd-12ab-34cd-56ef-1234567890ab</code></p></li>
/// <li>
/// <p>Key ARN: <code>arn:aws:kms:us-east-2:111122223333:key/1234abcd-12ab-34cd-56ef-1234567890ab</code></p></li>
/// <li>
/// <p>Alias name: <code>alias/ExampleAlias</code></p></li>
/// <li>
/// <p>Alias ARN: <code>arn:aws:kms:us-east-2:111122223333:alias/ExampleAlias</code></p></li>
/// </ul>
/// <p>To get the key ID and key ARN for a KMS key, use <code>ListKeys</code> or <code>DescribeKey</code>. To get the alias name and alias ARN, use <code>ListAliases</code>.</p>
pub fn get_key_id(&self) -> &::std::option::Option<::std::string::String> {
self.inner.get_key_id()
}
/// <p>Determines the type of data key pair that is generated.</p>
/// <p>The KMS rule that restricts the use of asymmetric RSA and SM2 KMS keys to encrypt and decrypt or to sign and verify (but not both), and the rule that permits you to use ECC KMS keys only to sign and verify, are not effective on data key pairs, which are used outside of KMS. The SM2 key spec is only available in China Regions.</p>
pub fn key_pair_spec(mut self, input: crate::types::DataKeyPairSpec) -> Self {
self.inner = self.inner.key_pair_spec(input);
self
}
/// <p>Determines the type of data key pair that is generated.</p>
/// <p>The KMS rule that restricts the use of asymmetric RSA and SM2 KMS keys to encrypt and decrypt or to sign and verify (but not both), and the rule that permits you to use ECC KMS keys only to sign and verify, are not effective on data key pairs, which are used outside of KMS. The SM2 key spec is only available in China Regions.</p>
pub fn set_key_pair_spec(mut self, input: ::std::option::Option<crate::types::DataKeyPairSpec>) -> Self {
self.inner = self.inner.set_key_pair_spec(input);
self
}
/// <p>Determines the type of data key pair that is generated.</p>
/// <p>The KMS rule that restricts the use of asymmetric RSA and SM2 KMS keys to encrypt and decrypt or to sign and verify (but not both), and the rule that permits you to use ECC KMS keys only to sign and verify, are not effective on data key pairs, which are used outside of KMS. The SM2 key spec is only available in China Regions.</p>
pub fn get_key_pair_spec(&self) -> &::std::option::Option<crate::types::DataKeyPairSpec> {
self.inner.get_key_pair_spec()
}
///
/// Appends an item to `GrantTokens`.
///
/// To override the contents of this collection use [`set_grant_tokens`](Self::set_grant_tokens).
///
/// <p>A list of grant tokens.</p>
/// <p>Use a grant token when your permission to call this operation comes from a new grant that has not yet achieved <i>eventual consistency</i>. For more information, see <a href="https://docs.aws.amazon.com/kms/latest/developerguide/grants.html#grant_token">Grant token</a> and <a href="https://docs.aws.amazon.com/kms/latest/developerguide/grant-manage.html#using-grant-token">Using a grant token</a> in the <i>Key Management Service Developer Guide</i>.</p>
pub fn grant_tokens(mut self, input: impl ::std::convert::Into<::std::string::String>) -> Self {
self.inner = self.inner.grant_tokens(input.into());
self
}
/// <p>A list of grant tokens.</p>
/// <p>Use a grant token when your permission to call this operation comes from a new grant that has not yet achieved <i>eventual consistency</i>. For more information, see <a href="https://docs.aws.amazon.com/kms/latest/developerguide/grants.html#grant_token">Grant token</a> and <a href="https://docs.aws.amazon.com/kms/latest/developerguide/grant-manage.html#using-grant-token">Using a grant token</a> in the <i>Key Management Service Developer Guide</i>.</p>
pub fn set_grant_tokens(mut self, input: ::std::option::Option<::std::vec::Vec<::std::string::String>>) -> Self {
self.inner = self.inner.set_grant_tokens(input);
self
}
/// <p>A list of grant tokens.</p>
/// <p>Use a grant token when your permission to call this operation comes from a new grant that has not yet achieved <i>eventual consistency</i>. For more information, see <a href="https://docs.aws.amazon.com/kms/latest/developerguide/grants.html#grant_token">Grant token</a> and <a href="https://docs.aws.amazon.com/kms/latest/developerguide/grant-manage.html#using-grant-token">Using a grant token</a> in the <i>Key Management Service Developer Guide</i>.</p>
pub fn get_grant_tokens(&self) -> &::std::option::Option<::std::vec::Vec<::std::string::String>> {
self.inner.get_grant_tokens()
}
/// <p>A signed <a href="https://docs.aws.amazon.com/AWSEC2/latest/UserGuide/nitro-enclave-how.html#term-attestdoc">attestation document</a> from an Amazon Web Services Nitro enclave and the encryption algorithm to use with the enclave's public key. The only valid encryption algorithm is <code>RSAES_OAEP_SHA_256</code>.</p>
/// <p>This parameter only supports attestation documents for Amazon Web Services Nitro Enclaves. To call DeriveSharedSecret for an Amazon Web Services Nitro Enclaves, use the <a href="https://docs.aws.amazon.com/enclaves/latest/user/developing-applications.html#sdk">Amazon Web Services Nitro Enclaves SDK</a> to generate the attestation document and then use the Recipient parameter from any Amazon Web Services SDK to provide the attestation document for the enclave.</p>
/// <p>When you use this parameter, instead of returning a plaintext copy of the private data key, KMS encrypts the plaintext private data key under the public key in the attestation document, and returns the resulting ciphertext in the <code>CiphertextForRecipient</code> field in the response. This ciphertext can be decrypted only with the private key in the enclave. The <code>CiphertextBlob</code> field in the response contains a copy of the private data key encrypted under the KMS key specified by the <code>KeyId</code> parameter. The <code>PrivateKeyPlaintext</code> field in the response is null or empty.</p>
/// <p>For information about the interaction between KMS and Amazon Web Services Nitro Enclaves, see <a href="https://docs.aws.amazon.com/kms/latest/developerguide/services-nitro-enclaves.html">How Amazon Web Services Nitro Enclaves uses KMS</a> in the <i>Key Management Service Developer Guide</i>.</p>
pub fn recipient(mut self, input: crate::types::RecipientInfo) -> Self {
self.inner = self.inner.recipient(input);
self
}
/// <p>A signed <a href="https://docs.aws.amazon.com/AWSEC2/latest/UserGuide/nitro-enclave-how.html#term-attestdoc">attestation document</a> from an Amazon Web Services Nitro enclave and the encryption algorithm to use with the enclave's public key. The only valid encryption algorithm is <code>RSAES_OAEP_SHA_256</code>.</p>
/// <p>This parameter only supports attestation documents for Amazon Web Services Nitro Enclaves. To call DeriveSharedSecret for an Amazon Web Services Nitro Enclaves, use the <a href="https://docs.aws.amazon.com/enclaves/latest/user/developing-applications.html#sdk">Amazon Web Services Nitro Enclaves SDK</a> to generate the attestation document and then use the Recipient parameter from any Amazon Web Services SDK to provide the attestation document for the enclave.</p>
/// <p>When you use this parameter, instead of returning a plaintext copy of the private data key, KMS encrypts the plaintext private data key under the public key in the attestation document, and returns the resulting ciphertext in the <code>CiphertextForRecipient</code> field in the response. This ciphertext can be decrypted only with the private key in the enclave. The <code>CiphertextBlob</code> field in the response contains a copy of the private data key encrypted under the KMS key specified by the <code>KeyId</code> parameter. The <code>PrivateKeyPlaintext</code> field in the response is null or empty.</p>
/// <p>For information about the interaction between KMS and Amazon Web Services Nitro Enclaves, see <a href="https://docs.aws.amazon.com/kms/latest/developerguide/services-nitro-enclaves.html">How Amazon Web Services Nitro Enclaves uses KMS</a> in the <i>Key Management Service Developer Guide</i>.</p>
pub fn set_recipient(mut self, input: ::std::option::Option<crate::types::RecipientInfo>) -> Self {
self.inner = self.inner.set_recipient(input);
self
}
/// <p>A signed <a href="https://docs.aws.amazon.com/AWSEC2/latest/UserGuide/nitro-enclave-how.html#term-attestdoc">attestation document</a> from an Amazon Web Services Nitro enclave and the encryption algorithm to use with the enclave's public key. The only valid encryption algorithm is <code>RSAES_OAEP_SHA_256</code>.</p>
/// <p>This parameter only supports attestation documents for Amazon Web Services Nitro Enclaves. To call DeriveSharedSecret for an Amazon Web Services Nitro Enclaves, use the <a href="https://docs.aws.amazon.com/enclaves/latest/user/developing-applications.html#sdk">Amazon Web Services Nitro Enclaves SDK</a> to generate the attestation document and then use the Recipient parameter from any Amazon Web Services SDK to provide the attestation document for the enclave.</p>
/// <p>When you use this parameter, instead of returning a plaintext copy of the private data key, KMS encrypts the plaintext private data key under the public key in the attestation document, and returns the resulting ciphertext in the <code>CiphertextForRecipient</code> field in the response. This ciphertext can be decrypted only with the private key in the enclave. The <code>CiphertextBlob</code> field in the response contains a copy of the private data key encrypted under the KMS key specified by the <code>KeyId</code> parameter. The <code>PrivateKeyPlaintext</code> field in the response is null or empty.</p>
/// <p>For information about the interaction between KMS and Amazon Web Services Nitro Enclaves, see <a href="https://docs.aws.amazon.com/kms/latest/developerguide/services-nitro-enclaves.html">How Amazon Web Services Nitro Enclaves uses KMS</a> in the <i>Key Management Service Developer Guide</i>.</p>
pub fn get_recipient(&self) -> &::std::option::Option<crate::types::RecipientInfo> {
self.inner.get_recipient()
}
/// <p>Checks if your request will succeed. <code>DryRun</code> is an optional parameter.</p>
/// <p>To learn more about how to use this parameter, see <a href="https://docs.aws.amazon.com/kms/latest/developerguide/programming-dryrun.html">Testing your KMS API calls</a> in the <i>Key Management Service Developer Guide</i>.</p>
pub fn dry_run(mut self, input: bool) -> Self {
self.inner = self.inner.dry_run(input);
self
}
/// <p>Checks if your request will succeed. <code>DryRun</code> is an optional parameter.</p>
/// <p>To learn more about how to use this parameter, see <a href="https://docs.aws.amazon.com/kms/latest/developerguide/programming-dryrun.html">Testing your KMS API calls</a> in the <i>Key Management Service Developer Guide</i>.</p>
pub fn set_dry_run(mut self, input: ::std::option::Option<bool>) -> Self {
self.inner = self.inner.set_dry_run(input);
self
}
/// <p>Checks if your request will succeed. <code>DryRun</code> is an optional parameter.</p>
/// <p>To learn more about how to use this parameter, see <a href="https://docs.aws.amazon.com/kms/latest/developerguide/programming-dryrun.html">Testing your KMS API calls</a> in the <i>Key Management Service Developer Guide</i>.</p>
pub fn get_dry_run(&self) -> &::std::option::Option<bool> {
self.inner.get_dry_run()
}
}