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AWS Encryption SDK for Pythonkode contoh
Contoh berikut menunjukkan kepada Anda cara menggunakanAWS Encryption SDK for Pythonmengenkripsi dan mendekripsi data.
Contoh di bagian ini menunjukkan cara menggunakanversi 2.0.xdan setelahnyaAWS Encryption SDK for Python. Untuk contoh yang menggunakan versi sebelumnya, temukan rilis Anda diRilis
Topik
Mengenkripsi dan mendekripsi string
Contoh berikut menunjukkan kepada Anda cara menggunakanAWS Encryption SDKmengenkripsi dan mendekripsi string. Contoh ini menggunakanAWS KMS keydiAWS Key Management Service(AWS KMS)
Saat mengenkripsi,StrictAwsKmsMasterKeyProvider
konstruktor mengambil ID kunci, ARN kunci, atau ARN alias. Saat mendekripsi, itumembutuhkan ARN kunci. Dalam kasus ini, karenakeyArn
digunakan untuk mengenkripsi dan mendekripsi, nilainya harus menjadi ARN kunci. Untuk informasi tentang ID untukAWS KMSkunci, lihatPengidentifikasi kuncidiAWS Key Management ServicePanduan Pengembang.
# Copyright 2017 Amazon.com, Inc. or its affiliates. All Rights Reserved. # # Licensed under the Apache License, Version 2.0 (the "License"). You # may not use this file except in compliance with the License. A copy of # the License is located at # # http://aws.amazon.com/apache2.0/ # # or in the "license" file accompanying this file. This file is # distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF # ANY KIND, either express or implied. See the License for the specific # language governing permissions and limitations under the License. """Example showing basic encryption and decryption of a value already in memory.""" import aws_encryption_sdk from aws_encryption_sdk import CommitmentPolicy def cycle_string(key_arn, source_plaintext, botocore_session=None): """Encrypts and then decrypts a string under an &KMS; key. :param str key_arn: Amazon Resource Name (ARN) of the &KMS; key :param bytes source_plaintext: Data to encrypt :param botocore_session: existing botocore session instance :type botocore_session: botocore.session.Session """ # Set up an encryption client with an explicit commitment policy. If you do not explicitly choose a # commitment policy, REQUIRE_ENCRYPT_REQUIRE_DECRYPT is used by default. client = aws_encryption_sdk.EncryptionSDKClient(commitment_policy=CommitmentPolicy.REQUIRE_ENCRYPT_REQUIRE_DECRYPT) # Create an AWS KMS master key provider kms_kwargs = dict(key_ids=[key_arn]) if botocore_session is not None: kms_kwargs["botocore_session"] = botocore_session master_key_provider = aws_encryption_sdk.StrictAwsKmsMasterKeyProvider(**kms_kwargs) # Encrypt the plaintext source data ciphertext, encryptor_header = client.encrypt(source=source_plaintext, key_provider=master_key_provider) # Decrypt the ciphertext cycled_plaintext, decrypted_header = client.decrypt(source=ciphertext, key_provider=master_key_provider) # Verify that the "cycled" (encrypted, then decrypted) plaintext is identical to the source plaintext assert cycled_plaintext == source_plaintext # Verify that the encryption context used in the decrypt operation includes all key pairs from # the encrypt operation. (The SDK can add pairs, so don't require an exact match.) # # In production, always use a meaningful encryption context. In this sample, we omit the # encryption context (no key pairs). assert all( pair in decrypted_header.encryption_context.items() for pair in encryptor_header.encryption_context.items() )
Mengenkripsi dan mendekripsi aliran byte
Contoh berikut menunjukkan kepada Anda cara menggunakanAWS Encryption SDKmengenkripsi dan mendekripsi aliran byte. Contoh ini tidak menggunakanAWS. Menggunakan statis, sementara penyedia kunci master.
Saat mengenkripsi, contoh ini menggunakan rangkaian algoritma alternatif tanpatanda tangan digital(AES_256_GCM_HKDF_SHA512_COMMIT_KEY
). Suite algoritma ini sesuai bila pengguna yang mengenkripsi dan mendekripsi data sama-sama dipercaya. Kemudian, saat mendekripsi, contohnya menggunakandecrypt-unsigned
modus streaming, yang gagal jika bertemu ciphertext ditandatangani. Parameterdecrypt-unsigned
mode streaming diperkenalkan diAWS Encryption SDKversi 1.9.xdan 2.2.x.
# Copyright 2017 Amazon.com, Inc. or its affiliates. All Rights Reserved. # # Licensed under the Apache License, Version 2.0 (the "License"). You # may not use this file except in compliance with the License. A copy of # the License is located at # # http://aws.amazon.com/apache2.0/ # # or in the "license" file accompanying this file. This file is # distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF # ANY KIND, either express or implied. See the License for the specific # language governing permissions and limitations under the License. """Example showing creation and use of a RawMasterKeyProvider.""" import filecmp import os import aws_encryption_sdk from aws_encryption_sdk.identifiers import Algorithm, CommitmentPolicy, EncryptionKeyType, WrappingAlgorithm from aws_encryption_sdk.internal.crypto.wrapping_keys import WrappingKey from aws_encryption_sdk.key_providers.raw import RawMasterKeyProvider class StaticRandomMasterKeyProvider(RawMasterKeyProvider): """Randomly generates 256-bit keys for each unique key ID.""" provider_id = "static-random" def __init__(self, **kwargs): # pylint: disable=unused-argument """Initialize empty map of keys.""" self._static_keys = {} def _get_raw_key(self, key_id): """Returns a static, randomly-generated symmetric key for the specified key ID. :param str key_id: Key ID :returns: Wrapping key that contains the specified static key :rtype: :class:`aws_encryption_sdk.internal.crypto.WrappingKey` """ try: static_key = self._static_keys[key_id] except KeyError: static_key = os.urandom(32) self._static_keys[key_id] = static_key return WrappingKey( wrapping_algorithm=WrappingAlgorithm.AES_256_GCM_IV12_TAG16_NO_PADDING, wrapping_key=static_key, wrapping_key_type=EncryptionKeyType.SYMMETRIC, ) def cycle_file(source_plaintext_filename): """Encrypts and then decrypts a file under a custom static master key provider. :param str source_plaintext_filename: Filename of file to encrypt """ # Set up an encryption client with an explicit commitment policy. Note that if you do not explicitly choose a # commitment policy, REQUIRE_ENCRYPT_REQUIRE_DECRYPT is used by default. client = aws_encryption_sdk.EncryptionSDKClient(commitment_policy=CommitmentPolicy.REQUIRE_ENCRYPT_REQUIRE_DECRYPT) # Create a static random master key provider key_id = os.urandom(8) master_key_provider = StaticRandomMasterKeyProvider() master_key_provider.add_master_key(key_id) ciphertext_filename = source_plaintext_filename + ".encrypted" cycled_plaintext_filename = source_plaintext_filename + ".decrypted" # Encrypt the plaintext source data # We can use an unsigning algorithm suite here under the assumption that the contexts that encrypt # and decrypt are equally trusted. with open(source_plaintext_filename, "rb") as plaintext, open(ciphertext_filename, "wb") as ciphertext: with client.stream( algorithm=Algorithm.AES_256_GCM_HKDF_SHA512_COMMIT_KEY, mode="e", source=plaintext, key_provider=master_key_provider, ) as encryptor: for chunk in encryptor: ciphertext.write(chunk) # Decrypt the ciphertext # We can use the recommended "decrypt-unsigned" streaming mode since we encrypted with an unsigned algorithm suite. with open(ciphertext_filename, "rb") as ciphertext, open(cycled_plaintext_filename, "wb") as plaintext: with client.stream(mode="decrypt-unsigned", source=ciphertext, key_provider=master_key_provider) as decryptor: for chunk in decryptor: plaintext.write(chunk) # Verify that the "cycled" (encrypted, then decrypted) plaintext is identical to the source # plaintext assert filecmp.cmp(source_plaintext_filename, cycled_plaintext_filename) # Verify that the encryption context used in the decrypt operation includes all key pairs from # the encrypt operation # # In production, always use a meaningful encryption context. In this sample, we omit the # encryption context (no key pairs). assert all( pair in decryptor.header.encryption_context.items() for pair in encryptor.header.encryption_context.items() ) return ciphertext_filename, cycled_plaintext_filename
Mengenkripsi dan mendekripsi aliran byte dengan beberapa penyedia kunci master
Contoh berikut menunjukkan kepada Anda cara menggunakanAWS Encryption SDKdengan lebih dari satu penyedia kunci utama. Menggunakan lebih dari satu master key provider menciptakan redundansi jika satu master key provider tidak tersedia untuk dekripsi. Contoh ini menggunakanAWS KMS keydan key pair RSA sebagai kunci master.
Contoh ini mengenkripsi dengansuite algoritma standar, yang meliputitanda tangan digital. Saat streaming,AWS Encryption SDKrilis plaintext setelah pemeriksaan integritas, tapi sebelum telah diverifikasi tanda tangan digital. Untuk menghindari penggunaan plaintext sampai tanda tangan diverifikasi, contoh ini buffer plaintext, dan menulisnya ke disk hanya ketika dekripsi dan verifikasi selesai.
# Copyright 2017 Amazon.com, Inc. or its affiliates. All Rights Reserved. # # Licensed under the Apache License, Version 2.0 (the "License"). You # may not use this file except in compliance with the License. A copy of # the License is located at # # http://aws.amazon.com/apache2.0/ # # or in the "license" file accompanying this file. This file is # distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF # ANY KIND, either express or implied. See the License for the specific # language governing permissions and limitations under the License. """Example showing creation of a RawMasterKeyProvider, how to use multiple master key providers to encrypt, and demonstrating that each master key provider can then be used independently to decrypt the same encrypted message. """ import filecmp import os from cryptography.hazmat.backends import default_backend from cryptography.hazmat.primitives import serialization from cryptography.hazmat.primitives.asymmetric import rsa import aws_encryption_sdk from aws_encryption_sdk.identifiers import CommitmentPolicy, EncryptionKeyType, WrappingAlgorithm from aws_encryption_sdk.internal.crypto.wrapping_keys import WrappingKey from aws_encryption_sdk.key_providers.raw import RawMasterKeyProvider class StaticRandomMasterKeyProvider(RawMasterKeyProvider): """Randomly generates and provides 4096-bit RSA keys consistently per unique key id.""" provider_id = "static-random" def __init__(self, **kwargs): # pylint: disable=unused-argument """Initialize empty map of keys.""" self._static_keys = {} def _get_raw_key(self, key_id): """Retrieves a static, randomly generated, RSA key for the specified key id. :param str key_id: User-defined ID for the static key :returns: Wrapping key that contains the specified static key :rtype: :class:`aws_encryption_sdk.internal.crypto.WrappingKey` """ try: static_key = self._static_keys[key_id] except KeyError: private_key = rsa.generate_private_key(public_exponent=65537, key_size=4096, backend=default_backend()) static_key = private_key.private_bytes( encoding=serialization.Encoding.PEM, format=serialization.PrivateFormat.PKCS8, encryption_algorithm=serialization.NoEncryption(), ) self._static_keys[key_id] = static_key return WrappingKey( wrapping_algorithm=WrappingAlgorithm.RSA_OAEP_SHA1_MGF1, wrapping_key=static_key, wrapping_key_type=EncryptionKeyType.PRIVATE, ) def cycle_file(key_arn, source_plaintext_filename, botocore_session=None): """Encrypts and then decrypts a file using an AWS KMS master key provider and a custom static master key provider. Both master key providers are used to encrypt the plaintext file, so either one alone can decrypt it. :param str key_arn: Amazon Resource Name (ARN) of the &KMS; key (http://docs.aws.amazon.com/kms/latest/developerguide/viewing-keys.html) :param str source_plaintext_filename: Filename of file to encrypt :param botocore_session: existing botocore session instance :type botocore_session: botocore.session.Session """ # "Cycled" means encrypted and then decrypted ciphertext_filename = source_plaintext_filename + ".encrypted" cycled_kms_plaintext_filename = source_plaintext_filename + ".kms.decrypted" cycled_static_plaintext_filename = source_plaintext_filename + ".static.decrypted" # Set up an encryption client with an explicit commitment policy. Note that if you do not explicitly choose a # commitment policy, REQUIRE_ENCRYPT_REQUIRE_DECRYPT is used by default. client = aws_encryption_sdk.EncryptionSDKClient(commitment_policy=CommitmentPolicy.REQUIRE_ENCRYPT_REQUIRE_DECRYPT) # Create an AWS KMS master key provider kms_kwargs = dict(key_ids=[key_arn]) if botocore_session is not None: kms_kwargs["botocore_session"] = botocore_session kms_master_key_provider = aws_encryption_sdk.StrictAwsKmsMasterKeyProvider(**kms_kwargs) # Create a static master key provider and add a master key to it static_key_id = os.urandom(8) static_master_key_provider = StaticRandomMasterKeyProvider() static_master_key_provider.add_master_key(static_key_id) # Add the static master key provider to the AWS KMS master key provider # The resulting master key provider uses AWS KMS master keys to generate (and encrypt) # data keys and static master keys to create an additional encrypted copy of each data key. kms_master_key_provider.add_master_key_provider(static_master_key_provider) # Encrypt plaintext with both AWS KMS and static master keys with open(source_plaintext_filename, "rb") as plaintext, open(ciphertext_filename, "wb") as ciphertext: with client.stream(source=plaintext, mode="e", key_provider=kms_master_key_provider) as encryptor: for chunk in encryptor: ciphertext.write(chunk) # Decrypt the ciphertext with only the AWS KMS master key # Buffer the data in memory before writing to disk. This ensures verfication of the digital signature before returning plaintext. with open(ciphertext_filename, "rb") as ciphertext, open(cycled_kms_plaintext_filename, "wb") as plaintext: with client.stream( source=ciphertext, mode="d", key_provider=aws_encryption_sdk.StrictAwsKmsMasterKeyProvider(**kms_kwargs) ) as kms_decryptor: plaintext.write(kms_decryptor.read()) # Decrypt the ciphertext with only the static master key # Buffer the data in memory before writing to disk to ensure verfication of the signature before returning plaintext. with open(ciphertext_filename, "rb") as ciphertext, open(cycled_static_plaintext_filename, "wb") as plaintext: with client.stream(source=ciphertext, mode="d", key_provider=static_master_key_provider) as static_decryptor: plaintext.write(static_decryptor.read()) # Verify that the "cycled" (encrypted, then decrypted) plaintext is identical to the source plaintext assert filecmp.cmp(source_plaintext_filename, cycled_kms_plaintext_filename) assert filecmp.cmp(source_plaintext_filename, cycled_static_plaintext_filename) # Verify that the encryption context in the decrypt operation includes all key pairs from the # encrypt operation. # # In production, always use a meaningful encryption context. In this sample, we omit the # encryption context (no key pairs). assert all( pair in kms_decryptor.header.encryption_context.items() for pair in encryptor.header.encryption_context.items() ) assert all( pair in static_decryptor.header.encryption_context.items() for pair in encryptor.header.encryption_context.items() ) return (ciphertext_filename, cycled_kms_plaintext_filename, cycled_static_plaintext_filename)
Menggunakan caching kunci data untuk mengenkripsi pesan
Contoh berikut menunjukkan cara menggunakancaching kunci datadiAWS Encryption SDK for Python. Hal ini dirancang untuk menunjukkan kepada Anda bagaimana mengkonfigurasi sebuah instanceCache lokal(LocalCryptoMaterialsCache) dengan nilai kapasitas yang diperlukan dan instance darimanajer bahan kriptografi(caching CMM) denganAmbang batas keamanan cache.
Contoh yang sangat mendasar ini menciptakan fungsi yang mengenkripsi string tetap. Ini memungkinkan Anda menentukanAWS KMS key, ukuran cache yang diperlukan (kapasitas), dan nilai usia maksimum. Untuk contoh caching kunci data yang lebih kompleks dan nyata, lihatKode contoh caching kunci data.
Meskipun opsional, contoh ini juga menggunakankonteks enkripsidata tambahan yang diautentikasi. Ketika Anda mendekripsi data yang dienkripsi dengan konteks enkripsi, pastikan bahwa aplikasi Anda memverifikasi bahwa konteks enkripsi adalah konteks enkripsi yang Anda harapkan sebelum mengembalikan data plaintext ke pemanggil Anda. Konteks enkripsi adalah elemen praktik terbaik dari setiap enkripsi atau dekripsi operasi, tetapi memainkan peran khusus dalam caching kunci data. Untuk rincian selengkapnya, lihatKonteks enkripsi: Cara Pilih Entri Cache.
# Copyright 2017 Amazon.com, Inc. or its affiliates. All Rights Reserved. # # Licensed under the Apache License, Version 2.0 (the "License"). You # may not use this file except in compliance with the License. A copy of # the License is located at # # http://aws.amazon.com/apache2.0/ # # or in the "license" file accompanying this file. This file is # distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF # ANY KIND, either express or implied. See the License for the specific # language governing permissions and limitations under the License. """Example of encryption with data key caching.""" import aws_encryption_sdk from aws_encryption_sdk import CommitmentPolicy def encrypt_with_caching(kms_key_arn, max_age_in_cache, cache_capacity): """Encrypts a string using an &KMS; key and data key caching. :param str kms_key_arn: Amazon Resource Name (ARN) of the &KMS; key :param float max_age_in_cache: Maximum time in seconds that a cached entry can be used :param int cache_capacity: Maximum number of entries to retain in cache at once """ # Data to be encrypted my_data = "My plaintext data" # Security thresholds # Max messages (or max bytes per) data key are optional MAX_ENTRY_MESSAGES = 100 # Create an encryption context encryption_context = {"purpose": "test"} # Set up an encryption client with an explicit commitment policy. Note that if you do not explicitly choose a # commitment policy, REQUIRE_ENCRYPT_REQUIRE_DECRYPT is used by default. client = aws_encryption_sdk.EncryptionSDKClient(commitment_policy=CommitmentPolicy.REQUIRE_ENCRYPT_REQUIRE_DECRYPT) # Create a master key provider for the &KMS; key key_provider = aws_encryption_sdk.StrictAwsKmsMasterKeyProvider(key_ids=[kms_key_arn]) # Create a local cache cache = aws_encryption_sdk.LocalCryptoMaterialsCache(cache_capacity) # Create a caching CMM caching_cmm = aws_encryption_sdk.CachingCryptoMaterialsManager( master_key_provider=key_provider, cache=cache, max_age=max_age_in_cache, max_messages_encrypted=MAX_ENTRY_MESSAGES, ) # When the call to encrypt data specifies a caching CMM, # the encryption operation uses the data key cache specified # in the caching CMM encrypted_message, _header = client.encrypt( source=my_data, materials_manager=caching_cmm, encryption_context=encryption_context ) return encrypted_message