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Ejemplos del SDK de cifrado de AWS para Java
En los siguientes ejemplos se muestra cómo utilizar el SDK de cifrado de AWS para Java para cifrar y descifrar datos. Estos ejemplos muestran cómo utilizar la versión 3. x y versiones posteriores deSDK de cifrado de AWS para Java. Versión 3. x de SDK de cifrado de AWS para Java reemplaza a los proveedores de llaves maestras por llaveros. Para ver ejemplos que utilizan versiones anteriores, busca tu versión en la lista de versiones
Cifrado y descifrado de cadenas
En el siguiente ejemplo, se muestra cómo utilizar la versión 3. x de SDK de cifrado de AWS para Java para cifrar y descifrar cadenas. Antes de usar la cadena, conviértala en una matriz de bytes.
En este ejemplo se utiliza un AWS KMS anillo de claves. Al cifrar con un AWS KMS anillo de claves, puede usar un ID de clave, un ARN de clave, un nombre de alias o un ARN de alias para identificar las claves de KMS. Al descifrar, debe utilizar una clave ARN para identificar las claves de KMS.
Cuando se llama al método encryptData(), este devuelve un mensaje cifrado (CryptoResult) que incluye el texto cifrado, las claves de datos cifradas y el contexto de cifrado. Cuando llama a getResult en el objeto CryptoResult, se devuelve una versión de cadena codificada en base 64 del mensaje cifrado que puede pasar al método decryptData().
Del mismo modo, cuando llama a decryptData(), el objeto CryptoResult que devuelve contiene el mensaje en texto sin formato y un ID de AWS KMS key. Antes de que la aplicación devuelva el texto no cifrado, verifique que el ID de AWS KMS key y el contexto de cifrado del mensaje cifrado sean los que espera.
// 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. * * <p>Arguments: * * <ol> * <li>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 * </ol> */ 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<String, String> encryptionContext = Collections.singletonMap("ExampleContextKey", "ExampleContextValue"); // 4. Encrypt the data final CryptoResult<byte[], ?> encryptResult = crypto.encryptData(kmsKeyring, EXAMPLE_DATA, encryptionContext); final byte[] ciphertext = encryptResult.getResult(); // 5. Decrypt the data final CryptoResult<byte[], ?> 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); } }
Cifrado y descifrado de secuencias de bytes
En el ejemplo siguiente se muestra cómo utilizar el AWS Encryption SDK para cifrar y descifrar secuencias de bytes.
En este ejemplo se utiliza un anillo de claves AES sin procesar.
Al cifrar, en este ejemplo se utiliza el método AwsCrypto.builder()
.withEncryptionAlgorithm() para especificar un conjunto de algoritmos sin firmas digitales. Al descifrar, para garantizar que el texto cifrado no esté firmado, en este ejemplo se utiliza el método createUnsignedMessageDecryptingStream(). El createUnsignedMessageDecryptingStream() método falla si encuentra un texto cifrado con una firma digital.
Si está cifrando con el conjunto de algoritmos predeterminado, que incluye firmas digitales, utilice el método createDecryptingStream() en su lugar, como se muestra en el siguiente ejemplo.
// 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; /** * <p> * Encrypts and then decrypts a file under a random key. * * <p> * Arguments: * <ol> * <li>Name of file containing plaintext data to encrypt * </ol> * * <p> * 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<String, String> 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<JceMasterKey> 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<JceMasterKey> 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"); } }
Cifrar y descifrar secuencias de bytes con un conjunto de claves múltiples
En el siguiente ejemplo, se muestra cómo utilizarla con un conjunto de claves múltiples. AWS Encryption SDK Cuando se utiliza un conjunto de claves múltiple para cifrar datos, cualquiera de las claves de encapsulación en cualquiera de los conjuntos de claves puede descifrar dichos datos. En este ejemplo, se utiliza un AWS KMSllavero y un llavero RSA sin procesar como llaveros secundarios.
En este ejemplo, se cifra con el conjunto de algoritmos predeterminado, que incluye una firma digital. Al transmitir, el AWS Encryption SDK publica el texto sin formato después de las comprobaciones de integridad, pero antes de comprobar la firma digital. Para evitar utilizar el texto sin formato hasta que se compruebe la firma, en este ejemplo se almacena el texto sin formato en búfer y se graba en el disco únicamente cuando se han completado el descifrado y la verificación.
// 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; /** * <p> * Encrypts a file using both AWS KMS Key and an asymmetric key pair. * * <p> * Arguments: * <ol> * <li>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 * * <li>Name of file containing plaintext data to encrypt * </ol> * <p> * 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. * <p> * 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. * <p> * 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()); } }
