Te recomendamos usar la primitiva AEAD determinista con el tipo de clave AES256_SIV.
La primitiva de encriptación autenticada determinista con datos asociados (AEAD determinista) produce textos cifrados estables: encriptar un texto simple determinado siempre muestra el mismo texto cifrado. Es simétrica, lo que significa que usa una sola clave para la encriptación y la desencriptación.
Con los siguientes ejemplos, puedes comenzar a usar la primitiva de AEAD determinista:
C++
// A command-line utility for testing Tink Deterministic AEAD. #include <iostream> #include <memory> #include <ostream> #include <string> #include "absl/flags/flag.h" #include "absl/flags/parse.h" #include "absl/log/check.h" #include "absl/strings/string_view.h" #include "tink/config/global_registry.h" #include "tink/daead/deterministic_aead_config.h" #include "tink/deterministic_aead.h" #include "util/util.h" #include "tink/keyset_handle.h" #include "tink/util/status.h" ABSL_FLAG(std::string, keyset_filename, "", "Keyset file in JSON format"); ABSL_FLAG(std::string, mode, "", "Mode of operation {encrypt|decrypt}"); ABSL_FLAG(std::string, input_filename, "", "Filename to operate on"); ABSL_FLAG(std::string, output_filename, "", "Output file name"); ABSL_FLAG(std::string, associated_data, "", "Associated data for Deterministic AEAD (default: empty"); namespace { using ::crypto::tink::DeterministicAead; using ::crypto::tink::DeterministicAeadConfig; using ::crypto::tink::KeysetHandle; using ::crypto::tink::util::Status; using ::crypto::tink::util::StatusOr; constexpr absl::string_view kEncrypt = "encrypt"; constexpr absl::string_view kDecrypt = "decrypt"; void ValidateParams() { // ... } } // namespace namespace tink_cc_examples { // Deterministic AEAD example CLI implementation. Status DeterministicAeadCli(absl::string_view mode, const std::string& keyset_filename, const std::string& input_filename, const std::string& output_filename, absl::string_view associated_data) { Status result = DeterministicAeadConfig::Register(); if (!result.ok()) return result; // Read keyset from file. StatusOr<std::unique_ptr<KeysetHandle>> keyset_handle = ReadJsonCleartextKeyset(keyset_filename); if (!keyset_handle.ok()) return keyset_handle.status(); // Get the primitive. StatusOr<std::unique_ptr<DeterministicAead>> daead = (*keyset_handle) ->GetPrimitive<crypto::tink::DeterministicAead>( crypto::tink::ConfigGlobalRegistry()); if (!daead.ok()) return daead.status(); // Read the input. StatusOr<std::string> input_file_content = ReadFile(input_filename); if (!input_file_content.ok()) return input_file_content.status(); // Compute the output. std::string output; if (mode == kEncrypt) { StatusOr<std::string> result = (*daead)->EncryptDeterministically( *input_file_content, associated_data); if (!result.ok()) return result.status(); output = *result; } else if (mode == kDecrypt) { StatusOr<std::string> result = (*daead)->DecryptDeterministically( *input_file_content, associated_data); if (!result.ok()) return result.status(); output = *result; } // Write output to file. return WriteToFile(output, output_filename); } } // namespace tink_cc_examples int main(int argc, char** argv) { absl::ParseCommandLine(argc, argv); ValidateParams(); std::string mode = absl::GetFlag(FLAGS_mode); std::string keyset_filename = absl::GetFlag(FLAGS_keyset_filename); std::string input_filename = absl::GetFlag(FLAGS_input_filename); std::string output_filename = absl::GetFlag(FLAGS_output_filename); std::string associated_data = absl::GetFlag(FLAGS_associated_data); std::clog << "Using keyset from file " << keyset_filename << " to Deterministic AEAD-" << mode << " file " << input_filename << " with associated data '" << associated_data << "'." << std::endl; std::clog << "The resulting output will be written to " << output_filename << "." << std::endl; CHECK_OK(tink_cc_examples::DeterministicAeadCli( mode, keyset_filename, input_filename, output_filename, associated_data)); return 0; }
Go
import ( "bytes" "fmt" "log" "github.com/tink-crypto/tink-go/v2/daead" "github.com/tink-crypto/tink-go/v2/insecurecleartextkeyset" "github.com/tink-crypto/tink-go/v2/keyset" ) func Example() { // A keyset created with "tinkey create-keyset --key-template=AES256_SIV". Note // that this keyset has the secret key information in cleartext. jsonKeyset := `{ "key": [{ "keyData": { "keyMaterialType": "SYMMETRIC", "typeUrl": "type.googleapis.com/google.crypto.tink.AesSivKey", "value": "EkAl9HCMmKTN1p3V186uhZpJQ+tivyc4IKyE+opg6SsEbWQ/WesWHzwCRrlgRuxdaggvgMzwWhjPnkk9gptBnGLK" }, "keyId": 1919301694, "outputPrefixType": "TINK", "status": "ENABLED" }], "primaryKeyId": 1919301694 }` // Create a keyset handle from the cleartext keyset in the previous // step. The keyset handle provides abstract access to the underlying keyset to // limit the exposure of accessing the raw key material. WARNING: In practice, // it is unlikely you will want to use a insecurecleartextkeyset, as it implies // that your key material is passed in cleartext, which is a security risk. // Consider encrypting it with a remote key in Cloud KMS, AWS KMS or HashiCorp Vault. // See https://github.com/google/tink/blob/master/docs/GOLANG-HOWTO.md#storing-and-loading-existing-keysets. keysetHandle, err := insecurecleartextkeyset.Read( keyset.NewJSONReader(bytes.NewBufferString(jsonKeyset))) if err != nil { log.Fatal(err) } // Retrieve the DAEAD primitive we want to use from the keyset handle. primitive, err := daead.New(keysetHandle) if err != nil { log.Fatal(err) } // Use the primitive to encrypt a message. In this case the primary key of the // keyset will be used (which is also the only key in this example). plaintext := []byte("message") associatedData := []byte("associated data") ciphertext, err := primitive.EncryptDeterministically(plaintext, associatedData) if err != nil { log.Fatal(err) } // Use the primitive to decrypt the message. Decrypt finds the correct key in // the keyset and decrypts the ciphertext. If no key is found or decryption // fails, it returns an error. decrypted, err := primitive.DecryptDeterministically(ciphertext, associatedData) if err != nil { log.Fatal(err) } fmt.Println(ciphertext) fmt.Println(string(decrypted)) // Output: // [1 114 102 56 62 150 98 146 84 99 211 36 127 214 229 231 157 56 143 192 250 132 32 153 124 244 238 112] // message }
Java
package deterministicaead; import static java.nio.charset.StandardCharsets.UTF_8; import com.google.crypto.tink.DeterministicAead; import com.google.crypto.tink.InsecureSecretKeyAccess; import com.google.crypto.tink.KeysetHandle; import com.google.crypto.tink.RegistryConfiguration; import com.google.crypto.tink.TinkJsonProtoKeysetFormat; import com.google.crypto.tink.daead.DeterministicAeadConfig; import java.nio.file.Files; import java.nio.file.Path; import java.nio.file.Paths; /** * A command-line utility for encrypting small files with Deterministic AEAD. * * <p>It loads cleartext keys from disk - this is not recommended! * * <p>It requires the following arguments: * * <ul> * <li>mode: Can be "encrypt" or "decrypt" to encrypt/decrypt the input to the output. * <li>key-file: Read the key material from this file. * <li>input-file: Read the input from this file. * <li>output-file: Write the result to this file. * <li>[optional] associated-data: Associated data used for the encryption or decryption. */ public final class DeterministicAeadExample { private static final String MODE_ENCRYPT = "encrypt"; private static final String MODE_DECRYPT = "decrypt"; public static void main(String[] args) throws Exception { if (args.length != 4 && args.length != 5) { System.err.printf("Expected 4 or 5 parameters, got %d\n", args.length); System.err.println( "Usage: java DeterministicAeadExample encrypt/decrypt key-file input-file output-file" + " [associated-data]"); System.exit(1); } String mode = args[0]; Path keyFile = Paths.get(args[1]); Path inputFile = Paths.get(args[2]); Path outputFile = Paths.get(args[3]); byte[] associatedData = new byte[0]; if (args.length == 5) { associatedData = args[4].getBytes(UTF_8); } // Initialise Tink: register all Deterministic AEAD key types with the Tink runtime DeterministicAeadConfig.register(); // Read the keyset into a KeysetHandle KeysetHandle handle = TinkJsonProtoKeysetFormat.parseKeyset( new String(Files.readAllBytes(keyFile), UTF_8), InsecureSecretKeyAccess.get()); // Get the primitive DeterministicAead daead = handle.getPrimitive(RegistryConfiguration.get(), DeterministicAead.class); // Use the primitive to encrypt/decrypt files. if (MODE_ENCRYPT.equals(mode)) { byte[] plaintext = Files.readAllBytes(inputFile); byte[] ciphertext = daead.encryptDeterministically(plaintext, associatedData); Files.write(outputFile, ciphertext); } else if (MODE_DECRYPT.equals(mode)) { byte[] ciphertext = Files.readAllBytes(inputFile); byte[] plaintext = daead.decryptDeterministically(ciphertext, associatedData); Files.write(outputFile, plaintext); } else { System.err.println("The first argument must be either encrypt or decrypt, got: " + mode); System.exit(1); } System.exit(0); } private DeterministicAeadExample() {} }
Python
import tink from tink import daead from tink import secret_key_access def example(): """Encrypt and decrypt using deterministic AEAD.""" # Register the deterministic AEAD key manager. This is needed to create a # DeterministicAead primitive later. daead.register() # A keyset created with "tinkey create-keyset --key-template=AES256_SIV". Note # that this keyset has the secret key information in cleartext. keyset = r"""{ "key": [{ "keyData": { "keyMaterialType": "SYMMETRIC", "typeUrl": "type.googleapis.com/google.crypto.tink.AesSivKey", "value": "EkAl9HCMmKTN1p3V186uhZpJQ+tivyc4IKyE+opg6SsEbWQ/WesWHzwCRrlgRuxdaggvgMzwWhjPnkk9gptBnGLK" }, "keyId": 1919301694, "outputPrefixType": "TINK", "status": "ENABLED" }], "primaryKeyId": 1919301694 }""" # Create a keyset handle from the cleartext keyset in the previous # step. The keyset handle provides abstract access to the underlying keyset to # limit the exposure of accessing the raw key material. WARNING: In practice, # it is unlikely you will want to use a cleartext_keyset_handle, as it implies # that your key material is passed in cleartext which is a security risk. keyset_handle = tink.json_proto_keyset_format.parse( keyset, secret_key_access.TOKEN ) # Retrieve the DeterministicAead primitive we want to use from the keyset # handle. primitive = keyset_handle.primitive(daead.DeterministicAead) # Use the primitive to encrypt a message. In this case the primary key of the # keyset will be used (which is also the only key in this example). ciphertext = primitive.encrypt_deterministically(b'msg', b'associated_data') # Use the primitive to decrypt the message. Decrypt finds the correct key in # the keyset and decrypts the ciphertext. If no key is found or decryption # fails, it raises an error. output = primitive.decrypt_deterministically(ciphertext, b'associated_data')
AEAD determinista
La primitiva de encriptación autenticada determinista con datos asociados (AEAD determinista) proporciona encriptación con una propiedad determinista: encriptar los mismos datos siempre genera el mismo texto cifrado. Este tipo de encriptación es útil para unir claves o para algunos esquemas de búsqueda en datos encriptados (consulta la RFC 5297, sección 1.3 para obtener más información). Debido a su propiedad determinista, las implementaciones de esta primitiva pueden provocar la pérdida de confidencialidad, ya que un atacante solo necesita averiguar el texto cifrado de un mensaje determinado para identificar otras instancias de ese mensaje.
La AEAD determinista tiene las siguientes propiedades:
- Secrecy: No se sabe nada sobre el texto simple, excepto su longitud y la igualdad de los textos simples repetidos.
- Autenticidad: Es imposible cambiar el texto simple encriptado que subyace al texto cifrado sin que se detecte.
- Simétrica: La encriptación del texto simple y la desencriptación del texto cifrado se realizan con la misma clave.
- Determinística: Siempre que no se cambie la clave principal, encriptar un texto sin formato dos veces con los mismos parámetros da como resultado el mismo texto cifrado.
Datos asociados
La AEAD determinista también se puede usar para vincular el texto cifrado a datos asociados específicos. Por ejemplo, si tienes una base de datos con los campos user-id y encrypted-medical-history, en esta situación, user-id se puede usar como datos asociados cuando se encripta encrypted-medical-history. Esto evita que un atacante mueva los antecedentes médicos de un usuario a otro.
Elige un tipo de clave
Recomendamos el tipo de clave AES256_SIV para todos los casos de uso.
Garantías de seguridad
- Tener al menos 80 bits de seguridad de autenticación
- El texto simple y los datos asociados pueden tener longitudes arbitrarias (dentro del rango de 0 a 232 bytes).
- Nivel de seguridad de 128 bits contra ataques de recuperación de claves y también en ataques de varios usuarios con hasta 232 claves, lo que significa que, si un adversario obtiene 232 textos cifrados del mismo mensaje encriptado con 232 claves, debe realizar 2128 cálculos para obtener una sola clave.
- La capacidad de encriptar de forma segura 238 mensajes, siempre que cada uno tenga menos de 1 MB de longitud.