기계 번역으로 제공되는 번역입니다. 제공된 번역과 원본 영어의 내용이 상충하는 경우에는 영어 버전이 우선합니다. # AWS Encryption SDK for Java 예제 다음 예제에서는를 사용하여 데이터를 암호화하고 복호화 AWS Encryption SDK for Java 하는 방법을 보여줍니다. 이 예제에서는 버전 3.*x* 이상을 사용하는 방법을 보여줍니다 AWS Encryption SDK for Java. 의 버전 3.*x*에는가 AWS Encryption SDK for Java 필요합니다 AWS SDK for Java 2.x. 의 버전 3.*x*는 [마스터 키 공급자](concepts.md#master-key-provider)를 키링으로 AWS Encryption SDK for Java 대체합니다. [키링 및 마스터 키 공급자](concepts.md#keyring) 이하 버전을 사용하는 예제의 경우 GitHub의 [aws-encryption-sdk-java](https://github.com/aws/aws-encryption-sdk-java/) 리포지토리의 [릴리스](https://github.com/aws/aws-encryption-sdk-java/releases) 목록에서 해당하는 릴리스를 찾을 수 있습니다. **Topics** + [문자열](#java-example-strings) + [바이트 스트림](#java-example-streams) + [여러 마스터 키 공급자를 사용하는 바이트 스트림](#java-example-multiple-providers) ## 문자열 암호화 및 복호화 다음 예제에서는의 버전 3.*x* AWS Encryption SDK for Java 를 사용하여 문자열을 암호화하고 복호화하는 방법을 보여줍니다. 문자열을 사용하기 전에 바이트 배열로 변환하세요. 이 예제에서는 [AWS KMS 키링](use-kms-keyring.md)을 사용합니다. AWS KMS 키링으로 암호화할 때 키 ID, 키 ARN, 별칭 이름 또는 별칭 ARN을 사용하여 KMS 키를 식별할 수 있습니다. 복호화할 때 키 ARN을 사용하여 KMS 키를 식별해야 합니다. `encryptData()` 메서드를 호출하면 사이퍼텍스트, 암호화된 데이터 키 및 암호화 컨텍스트를 포함하는 [암호화된 메시지](concepts.md#message)(`CryptoResult`)가 반환됩니다. `CryptoResult` 객체에서 `getResult`를 호출하면 `decryptData()` 메서드에 전달할 수 있는 [암호화된 메시지](message-format.md)의 base-64 인코딩 문자열 버전이 반환됩니다. 마찬가지로 `decryptData()`를 호출할 때 반환되는 `CryptoResult` 객체에는 일반 텍스트 메시지와 AWS KMS key ID가 포함됩니다. 애플리케이션이 일반 텍스트를 반환하기 전에 암호화된 메시지의 AWS KMS key ID와 암호화 컨텍스트가 예상한 것인지 확인합니다. ``` // Copyright Amazon.com Inc. or its affiliates. All Rights Reserved. // SPDX-License-Identifier: Apache-2.0 package com.amazonaws.crypto.keyrings; import com.amazonaws.encryptionsdk.AwsCrypto; import com.amazonaws.encryptionsdk.CommitmentPolicy; import com.amazonaws.encryptionsdk.CryptoResult; import software.amazon.cryptography.materialproviders.IKeyring; import software.amazon.cryptography.materialproviders.MaterialProviders; import software.amazon.cryptography.materialproviders.model.CreateAwsKmsMultiKeyringInput; import software.amazon.cryptography.materialproviders.model.MaterialProvidersConfig; import java.nio.charset.StandardCharsets; import java.util.Arrays; import java.util.Collections; import java.util.Map; /** * Encrypts and then decrypts data using an AWS KMS Keyring. * *

Arguments: * *

    *
  1. Key ARN: For help finding the Amazon Resource Name (ARN) of your AWS KMS customer master * key (CMK), see 'Viewing Keys' at * http://docs.aws.amazon.com/kms/latest/developerguide/viewing-keys.html *
*/ public class BasicEncryptionKeyringExample { private static final byte[] EXAMPLE_DATA = "Hello World".getBytes(StandardCharsets.UTF_8); public static void main(final String[] args) { final String keyArn = args[0]; encryptAndDecryptWithKeyring(keyArn); } public static void encryptAndDecryptWithKeyring(final String keyArn) { // 1. Instantiate the SDK // This builds the AwsCrypto client with the RequireEncryptRequireDecrypt commitment policy, // which means this client only encrypts using committing algorithm suites and enforces // that the client will only decrypt encrypted messages that were created with a committing // algorithm suite. // This is the default commitment policy if you build the client with // `AwsCrypto.builder().build()` // or `AwsCrypto.standard()`. final AwsCrypto crypto = AwsCrypto.builder() .withCommitmentPolicy(CommitmentPolicy.RequireEncryptRequireDecrypt) .build(); // 2. Create the AWS KMS keyring. // This example creates a multi keyring, which automatically creates the KMS client. final MaterialProviders materialProviders = MaterialProviders.builder() .MaterialProvidersConfig(MaterialProvidersConfig.builder().build()) .build(); final CreateAwsKmsMultiKeyringInput keyringInput = CreateAwsKmsMultiKeyringInput.builder().generator(keyArn).build(); final IKeyring kmsKeyring = materialProviders.CreateAwsKmsMultiKeyring(keyringInput); // 3. Create an encryption context // We recommend using an encryption context whenever possible // to protect integrity. This sample uses placeholder values. // For more information see: // blogs.aws.amazon.com/security/post/Tx2LZ6WBJJANTNW/How-to-Protect-the-Integrity-of-Your-Encrypted-Data-by-Using-AWS-Key-Management final Map encryptionContext = Collections.singletonMap("ExampleContextKey", "ExampleContextValue"); // 4. Encrypt the data final CryptoResult encryptResult = crypto.encryptData(kmsKeyring, EXAMPLE_DATA, encryptionContext); final byte[] ciphertext = encryptResult.getResult(); // 5. Decrypt the data final CryptoResult decryptResult = crypto.decryptData( kmsKeyring, ciphertext, // Verify that the encryption context in the result contains the // encryption context supplied to the encryptData method encryptionContext); // 6. Verify that the decrypted plaintext matches the original plaintext assert Arrays.equals(decryptResult.getResult(), EXAMPLE_DATA); } } ``` ## 바이트 스트림 암호화 및 복호화 다음 예제에서는를 사용하여 바이트 스트림을 암호화하고 복호화 AWS Encryption SDK 하는 방법을 보여줍니다. 이 예제에서는 [원시 AES 키링](use-raw-aes-keyring.md)을 사용합니다. 암호화할 때 이 예제에서는 `AwsCrypto.builder() .withEncryptionAlgorithm()` 메서드를 사용하여 [디지털 서명](concepts.md#digital-sigs)이 없는 알고리즘 제품군을 지정합니다. 이 예제에서는 복호화할 때 사이퍼텍스트에 서명이 없는지 확인하기 위해 `createUnsignedMessageDecryptingStream()` 메서드를 사용합니다. 디지털 서명이 있는 사이퍼텍스트가 발생하면 `createUnsignedMessageDecryptingStream()` 메서드가 실패합니다. 디지털 서명이 포함된 기본 알고리즘 제품군으로 암호화하는 경우 다음 예제와 같이 `createDecryptingStream()` 메서드를 대신 사용하세요. ``` // Copyright Amazon.com Inc. or its affiliates. All Rights Reserved. // SPDX-License-Identifier: Apache-2.0 package com.amazonaws.crypto.keyrings; import com.amazonaws.encryptionsdk.AwsCrypto; import com.amazonaws.encryptionsdk.CommitmentPolicy; import com.amazonaws.encryptionsdk.CryptoAlgorithm; import com.amazonaws.encryptionsdk.CryptoInputStream; import com.amazonaws.encryptionsdk.jce.JceMasterKey; import com.amazonaws.util.IOUtils; import software.amazon.cryptography.materialproviders.IKeyring; import software.amazon.cryptography.materialproviders.MaterialProviders; import software.amazon.cryptography.materialproviders.model.AesWrappingAlg; import software.amazon.cryptography.materialproviders.model.CreateRawAesKeyringInput; import software.amazon.cryptography.materialproviders.model.MaterialProvidersConfig; import java.io.FileInputStream; import java.io.FileOutputStream; import java.io.IOException; import java.nio.ByteBuffer; import java.security.SecureRandom; import java.util.Collections; import java.util.Map; import javax.crypto.SecretKey; import javax.crypto.spec.SecretKeySpec; /** *

* Encrypts and then decrypts a file under a random key. * *

* Arguments: *

    *
  1. Name of file containing plaintext data to encrypt *
* *

* This program demonstrates using a standard Java {@link SecretKey} object as a {@link IKeyring} to * encrypt and decrypt streaming data. */ public class FileStreamingKeyringExample { private static String srcFile; public static void main(String[] args) throws IOException { srcFile = args[0]; // In this example, we generate a random key. In practice, // you would get a key from an existing store SecretKey cryptoKey = retrieveEncryptionKey(); // Create a Raw Aes Keyring using the random key and an AES-GCM encryption algorithm final MaterialProviders materialProviders = MaterialProviders.builder() .MaterialProvidersConfig(MaterialProvidersConfig.builder().build()) .build(); final CreateRawAesKeyringInput keyringInput = CreateRawAesKeyringInput.builder() .wrappingKey(ByteBuffer.wrap(cryptoKey.getEncoded())) .keyNamespace("Example") .keyName("RandomKey") .wrappingAlg(AesWrappingAlg.ALG_AES128_GCM_IV12_TAG16) .build(); IKeyring keyring = materialProviders.CreateRawAesKeyring(keyringInput); // Instantiate the SDK. // This builds the AwsCrypto client with the RequireEncryptRequireDecrypt commitment policy, // which means this client only encrypts using committing algorithm suites and enforces // that the client will only decrypt encrypted messages that were created with a committing // algorithm suite. // This is the default commitment policy if you build the client with // `AwsCrypto.builder().build()` // or `AwsCrypto.standard()`. // This example encrypts with an algorithm suite that doesn't include signing for faster decryption, // since this use case assumes that the contexts that encrypt and decrypt are equally trusted. final AwsCrypto crypto = AwsCrypto.builder() .withCommitmentPolicy(CommitmentPolicy.RequireEncryptRequireDecrypt) .withEncryptionAlgorithm(CryptoAlgorithm.ALG_AES_256_GCM_HKDF_SHA512_COMMIT_KEY) .build(); // Create an encryption context to identify the ciphertext Map context = Collections.singletonMap("Example", "FileStreaming"); // Because the file might be too large to load into memory, we stream the data, instead of //loading it all at once. FileInputStream in = new FileInputStream(srcFile); CryptoInputStream encryptingStream = crypto.createEncryptingStream(keyring, in, context); FileOutputStream out = new FileOutputStream(srcFile + ".encrypted"); IOUtils.copy(encryptingStream, out); encryptingStream.close(); out.close(); // Decrypt the file. Verify the encryption context before returning the plaintext. // Since the data was encrypted using an unsigned algorithm suite, use the recommended // createUnsignedMessageDecryptingStream method, which only accepts unsigned messages. in = new FileInputStream(srcFile + ".encrypted"); CryptoInputStream decryptingStream = crypto.createUnsignedMessageDecryptingStream(keyring, in); // Does it contain the expected encryption context? if (!"FileStreaming".equals(decryptingStream.getCryptoResult().getEncryptionContext().get("Example"))) { throw new IllegalStateException("Bad encryption context"); } // Write the plaintext data to disk. out = new FileOutputStream(srcFile + ".decrypted"); IOUtils.copy(decryptingStream, out); decryptingStream.close(); out.close(); } /** * In practice, this key would be saved in a secure location. * For this demo, we generate a new random key for each operation. */ private static SecretKey retrieveEncryptionKey() { SecureRandom rnd = new SecureRandom(); byte[] rawKey = new byte[16]; // 128 bits rnd.nextBytes(rawKey); return new SecretKeySpec(rawKey, "AES"); } } ``` ## 다중 키 링을 사용하여 바이트 스트림 암호화 및 복호화 다음 예제에서는 [다중 키 링](use-multi-keyring.md)과 AWS Encryption SDK 함께를 사용하는 방법을 보여줍니다. 다중 키링을 사용하여 데이터를 암호화하는 경우 해당 키링의 모든 래핑 키로 해당 데이터를 복호화할 수 있습니다. 이 예제에서는 [AWS KMS 키링](use-kms-keyring.md)과 [Raw RSA 키링](use-raw-rsa-keyring.md)을 하위 키링으로 사용합니다. 이 예제는 [디지털 서명](concepts.md#digital-sigs)이 포함된 [기본 알고리즘 제품군](supported-algorithms.md)을 사용하여 암호화합니다. 스트리밍할 때는 무결성 검사 후 디지털 서명을 확인하기 전에 일반 텍스트를 AWS Encryption SDK 릴리스합니다. 서명이 확인될 때까지 일반 텍스트를 사용하지 않도록 이 예제에서는 일반 텍스트를 버퍼링하고 복호화 및 확인이 완료될 때만 디스크에 씁니다. ``` // Copyright Amazon.com Inc. or its affiliates. All Rights Reserved. // SPDX-License-Identifier: Apache-2.0 package com.amazonaws.crypto.keyrings; import com.amazonaws.encryptionsdk.AwsCrypto; import com.amazonaws.encryptionsdk.CommitmentPolicy; import com.amazonaws.encryptionsdk.CryptoOutputStream; import com.amazonaws.util.IOUtils; import software.amazon.cryptography.materialproviders.IKeyring; import software.amazon.cryptography.materialproviders.MaterialProviders; import software.amazon.cryptography.materialproviders.model.CreateAwsKmsMultiKeyringInput; import software.amazon.cryptography.materialproviders.model.CreateMultiKeyringInput; import software.amazon.cryptography.materialproviders.model.CreateRawRsaKeyringInput; import software.amazon.cryptography.materialproviders.model.MaterialProvidersConfig; import software.amazon.cryptography.materialproviders.model.PaddingScheme; import java.io.ByteArrayInputStream; import java.io.ByteArrayOutputStream; import java.io.FileInputStream; import java.io.FileOutputStream; import java.nio.ByteBuffer; import java.security.GeneralSecurityException; import java.security.KeyPair; import java.security.KeyPairGenerator; import java.util.Collections; /** *

* Encrypts a file using both AWS KMS Key and an asymmetric key pair. * *

* Arguments: *

    *
  1. Key ARN: For help finding the Amazon Resource Name (ARN) of your AWS KMS key, * see 'Viewing Keys' at http://docs.aws.amazon.com/kms/latest/developerguide/viewing-keys.html * *
  2. Name of file containing plaintext data to encrypt *
*

* You might use AWS Key Management Service (AWS KMS) for most encryption and decryption operations, but * still want the option of decrypting your data offline independently of AWS KMS. This sample * demonstrates one way to do this. *

* The sample encrypts data under both an AWS KMS key and an "escrowed" RSA key pair * so that either key alone can decrypt it. You might commonly use the AWS KMS key for decryption. However, * at any time, you can use the private RSA key to decrypt the ciphertext independent of AWS KMS. *

* This sample uses the RawRsaKeyring to generate a RSA public-private key pair * and saves the key pair in memory. In practice, you would store the private key in a secure offline * location, such as an offline HSM, and distribute the public key to your development team. */ public class EscrowedEncryptKeyringExample { private static ByteBuffer publicEscrowKey; private static ByteBuffer privateEscrowKey; public static void main(final String[] args) throws Exception { // This sample generates a new random key for each operation. // In practice, you would distribute the public key and save the private key in secure // storage. generateEscrowKeyPair(); final String kmsArn = args[0]; final String fileName = args[1]; standardEncrypt(kmsArn, fileName); standardDecrypt(kmsArn, fileName); escrowDecrypt(fileName); } private static void standardEncrypt(final String kmsArn, final String fileName) throws Exception { // Encrypt with the KMS key and the escrowed public key // 1. Instantiate the SDK // This builds the AwsCrypto client with the RequireEncryptRequireDecrypt commitment policy, // which means this client only encrypts using committing algorithm suites and enforces // that the client will only decrypt encrypted messages that were created with a committing // algorithm suite. // This is the default commitment policy if you build the client with // `AwsCrypto.builder().build()` // or `AwsCrypto.standard()`. final AwsCrypto crypto = AwsCrypto.builder() .withCommitmentPolicy(CommitmentPolicy.RequireEncryptRequireDecrypt) .build(); // 2. Create the AWS KMS keyring. // This example creates a multi keyring, which automatically creates the KMS client. final MaterialProviders matProv = MaterialProviders.builder() .MaterialProvidersConfig(MaterialProvidersConfig.builder().build()) .build(); final CreateAwsKmsMultiKeyringInput keyringInput = CreateAwsKmsMultiKeyringInput.builder() .generator(kmsArn) .build(); IKeyring kmsKeyring = matProv.CreateAwsKmsMultiKeyring(keyringInput); // 3. Create the Raw Rsa Keyring with Public Key. final CreateRawRsaKeyringInput encryptingKeyringInput = CreateRawRsaKeyringInput.builder() .keyName("Escrow") .keyNamespace("Escrow") .paddingScheme(PaddingScheme.OAEP_SHA512_MGF1) .publicKey(publicEscrowKey) .build(); IKeyring rsaPublicKeyring = matProv.CreateRawRsaKeyring(encryptingKeyringInput); // 4. Create the multi-keyring. final CreateMultiKeyringInput createMultiKeyringInput = CreateMultiKeyringInput.builder() .generator(kmsKeyring) .childKeyrings(Collections.singletonList(rsaPublicKeyring)) .build(); IKeyring multiKeyring = matProv.CreateMultiKeyring(createMultiKeyringInput); // 5. Encrypt the file // To simplify this code example, we omit the encryption context. Production code should always // use an encryption context. final FileInputStream in = new FileInputStream(fileName); final FileOutputStream out = new FileOutputStream(fileName + ".encrypted"); final CryptoOutputStream encryptingStream = crypto.createEncryptingStream(multiKeyring, out); IOUtils.copy(in, encryptingStream); in.close(); encryptingStream.close(); } private static void standardDecrypt(final String kmsArn, final String fileName) throws Exception { // Decrypt with the AWS KMS key and the escrow public key. // 1. Instantiate the SDK. // This builds the AwsCrypto client with the RequireEncryptRequireDecrypt commitment policy, // which means this client only encrypts using committing algorithm suites and enforces // that the client will only decrypt encrypted messages that were created with a committing // algorithm suite. // This is the default commitment policy if you build the client with // `AwsCrypto.builder().build()` // or `AwsCrypto.standard()`. final AwsCrypto crypto = AwsCrypto.builder() .withCommitmentPolicy(CommitmentPolicy.RequireEncryptRequireDecrypt) .build(); // 2. Create the AWS KMS keyring. // This example creates a multi keyring, which automatically creates the KMS client. final MaterialProviders matProv = MaterialProviders.builder() .MaterialProvidersConfig(MaterialProvidersConfig.builder().build()) .build(); final CreateAwsKmsMultiKeyringInput keyringInput = CreateAwsKmsMultiKeyringInput.builder() .generator(kmsArn) .build(); IKeyring kmsKeyring = matProv.CreateAwsKmsMultiKeyring(keyringInput); // 3. Create the Raw Rsa Keyring with Public Key. final CreateRawRsaKeyringInput encryptingKeyringInput = CreateRawRsaKeyringInput.builder() .keyName("Escrow") .keyNamespace("Escrow") .paddingScheme(PaddingScheme.OAEP_SHA512_MGF1) .publicKey(publicEscrowKey) .build(); IKeyring rsaPublicKeyring = matProv.CreateRawRsaKeyring(encryptingKeyringInput); // 4. Create the multi-keyring. final CreateMultiKeyringInput createMultiKeyringInput = CreateMultiKeyringInput.builder() .generator(kmsKeyring) .childKeyrings(Collections.singletonList(rsaPublicKeyring)) .build(); IKeyring multiKeyring = matProv.CreateMultiKeyring(createMultiKeyringInput); // 5. Decrypt the file // To simplify this code example, we omit the encryption context. Production code should always // use an encryption context. final FileInputStream in = new FileInputStream(fileName + ".encrypted"); final FileOutputStream out = new FileOutputStream(fileName + ".decrypted"); // Since we are using a signing algorithm suite, we avoid streaming decryption directly to the output file, // to ensure that the trailing signature is verified before writing any untrusted plaintext to disk. final ByteArrayOutputStream plaintextBuffer = new ByteArrayOutputStream(); final CryptoOutputStream decryptingStream = crypto.createDecryptingStream(multiKeyring, plaintextBuffer); IOUtils.copy(in, decryptingStream); in.close(); decryptingStream.close(); final ByteArrayInputStream plaintextReader = new ByteArrayInputStream(plaintextBuffer.toByteArray()); IOUtils.copy(plaintextReader, out); out.close(); } private static void escrowDecrypt(final String fileName) throws Exception { // You can decrypt the stream using only the private key. // This method does not call AWS KMS. // 1. Instantiate the SDK final AwsCrypto crypto = AwsCrypto.standard(); // 2. Create the Raw Rsa Keyring with Private Key. final MaterialProviders matProv = MaterialProviders.builder() .MaterialProvidersConfig(MaterialProvidersConfig.builder().build()) .build(); final CreateRawRsaKeyringInput encryptingKeyringInput = CreateRawRsaKeyringInput.builder() .keyName("Escrow") .keyNamespace("Escrow") .paddingScheme(PaddingScheme.OAEP_SHA512_MGF1) .publicKey(publicEscrowKey) .privateKey(privateEscrowKey) .build(); IKeyring escrowPrivateKeyring = matProv.CreateRawRsaKeyring(encryptingKeyringInput); // 3. Decrypt the file // To simplify this code example, we omit the encryption context. Production code should always // use an encryption context. final FileInputStream in = new FileInputStream(fileName + ".encrypted"); final FileOutputStream out = new FileOutputStream(fileName + ".deescrowed"); final CryptoOutputStream decryptingStream = crypto.createDecryptingStream(escrowPrivateKeyring, out); IOUtils.copy(in, decryptingStream); in.close(); decryptingStream.close(); } private static void generateEscrowKeyPair() throws GeneralSecurityException { final KeyPairGenerator kg = KeyPairGenerator.getInstance("RSA"); kg.initialize(4096); // Escrow keys should be very strong final KeyPair keyPair = kg.generateKeyPair(); publicEscrowKey = RawRsaKeyringExample.getPEMPublicKey(keyPair.getPublic()); privateEscrowKey = RawRsaKeyringExample.getPEMPrivateKey(keyPair.getPrivate()); } } ```