mirror of
https://github.com/bitwarden/android.git
synced 2024-12-24 01:48:25 +03:00
centralized crypto utils. keystore with rsa.
This commit is contained in:
parent
7a56141894
commit
93176989fd
4 changed files with 211 additions and 158 deletions
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@ -10,7 +10,6 @@ using Java.Math;
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using Android.Security.Keystore;
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using Android.App;
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using Plugin.Settings.Abstractions;
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using Javax.Crypto.Spec;
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using System.Collections.Generic;
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using Java.Util;
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@ -23,13 +22,12 @@ namespace Bit.Android.Services
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private const string KeyAlias = "bitwardenKey";
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private const string SettingsFormat = "ksSecured:{0}";
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private const string RsaMode = "RSA/ECB/PKCS1Padding";
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private const string AesMode = "AES/GCM/NoPadding";
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private const string AesKey = "ksSecured:aesKeyForService";
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private readonly ISettings _settings;
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private readonly KeyStore _keyStore;
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private readonly bool _oldAndroid = Build.VERSION.SdkInt < BuildVersionCodes.M;
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private readonly KeyStoreStorageService _oldKeyStorageService;
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private readonly ISecureStorageService _oldKeyStorageService;
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public KeyStoreBackedStorageService(ISettings settings)
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{
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@ -39,7 +37,7 @@ namespace Bit.Android.Services
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_keyStore = KeyStore.GetInstance(AndroidKeyStore);
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_keyStore.Load(null);
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GenerateKeys();
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GenerateRsaKey();
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GenerateAesKey();
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}
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@ -62,8 +60,28 @@ namespace Bit.Android.Services
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return TryGetAndMigrateFromOldKeyStore(key);
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}
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var cipherString = _settings.GetValueOrDefault<string>(formattedKey);
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return AesDecrypt(cipherString);
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var cs = _settings.GetValueOrDefault<string>(formattedKey);
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if(string.IsNullOrWhiteSpace(cs))
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{
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return null;
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}
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var aesKey = GetAesKey();
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if(aesKey == null)
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{
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return null;
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}
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try
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{
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return App.Utilities.Crypto.AesCbcDecrypt(new App.Models.CipherString(cs), aesKey);
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}
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catch
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{
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Console.WriteLine("Failed to decrypt from secure storage.");
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_settings.Remove(formattedKey);
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return null;
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}
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}
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public void Store(string key, byte[] dataBytes)
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@ -76,35 +94,41 @@ namespace Bit.Android.Services
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return;
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}
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var cipherString = AesEncrypt(dataBytes);
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_settings.AddOrUpdateValue(formattedKey, cipherString);
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var aesKey = GetAesKey();
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if(aesKey == null)
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{
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return;
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}
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try
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{
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var cipherString = App.Utilities.Crypto.AesCbcEncrypt(dataBytes, aesKey);
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_settings.AddOrUpdateValue(formattedKey, cipherString.EncryptedString);
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}
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catch
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{
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Console.WriteLine("Failed to encrypt to secure storage.");
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}
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}
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private byte[] RandomBytes(int length)
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{
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var key = new byte[length];
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var secureRandom = new SecureRandom();
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secureRandom.NextBytes(key);
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return key;
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}
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private void GenerateKeys()
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private void GenerateRsaKey()
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{
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if(_keyStore.ContainsAlias(KeyAlias))
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{
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return;
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}
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var start = Calendar.Instance;
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var end = Calendar.Instance;
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end.Add(CalendarField.Year, 30);
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var subject = new X500Principal($"CN={KeyAlias}");
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if(_oldAndroid)
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{
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var start = Calendar.Instance;
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var end = Calendar.Instance;
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end.Add(CalendarField.Year, 30);
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var gen = KeyPairGenerator.GetInstance(KeyProperties.KeyAlgorithmRsa, AndroidKeyStore);
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var spec = new KeyPairGeneratorSpec.Builder(Application.Context)
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.SetAlias(KeyAlias)
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.SetSubject(new X500Principal($"CN={KeyAlias}"))
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.SetSubject(subject)
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.SetSerialNumber(BigInteger.Ten)
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.SetStartDate(start.Time)
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.SetEndDate(end.Time)
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@ -115,10 +139,12 @@ namespace Bit.Android.Services
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}
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else
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{
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var gen = KeyGenerator.GetInstance(KeyProperties.KeyAlgorithmAes, AndroidKeyStore);
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var gen = KeyGenerator.GetInstance(KeyProperties.KeyAlgorithmRsa, AndroidKeyStore);
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var spec = new KeyGenParameterSpec.Builder(KeyAlias, KeyStorePurpose.Decrypt | KeyStorePurpose.Encrypt)
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.SetBlockModes(KeyProperties.BlockModeGcm)
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.SetEncryptionPaddings(KeyProperties.EncryptionPaddingNone)
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.SetCertificateSubject(subject)
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.SetCertificateSerialNumber(BigInteger.Ten)
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.SetKeyValidityStart(start.Time)
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.SetKeyValidityEnd(end.Time)
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.Build();
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gen.Init(spec);
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@ -126,63 +152,44 @@ namespace Bit.Android.Services
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}
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}
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private void GenerateAesKey()
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{
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if(!_oldAndroid)
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{
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return;
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}
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if(_settings.Contains(AesKey))
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{
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return;
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}
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var key = RandomBytes(16);
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var encKey = RsaEncrypt(key);
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_settings.AddOrUpdateValue(AesKey, Convert.ToBase64String(encKey));
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}
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private IKey GetAesKey()
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{
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if(_oldAndroid)
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{
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var encKey = _settings.GetValueOrDefault<string>(AesKey);
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var encKeyBytes = Convert.FromBase64String(encKey);
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var key = RsaDecrypt(encKeyBytes);
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return new SecretKeySpec(key, "AES");
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}
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else
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{
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return _keyStore.GetKey(KeyAlias, null);
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}
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}
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private KeyStore.PrivateKeyEntry GetRsaKeyEntry()
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{
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return _keyStore.GetEntry(KeyAlias, null) as KeyStore.PrivateKeyEntry;
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}
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private string AesEncrypt(byte[] input)
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private void GenerateAesKey()
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{
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var cipher = Cipher.GetInstance(AesMode);
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cipher.Init(CipherMode.EncryptMode, GetAesKey());
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var encBytes = cipher.DoFinal(input);
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var ivBytes = cipher.GetIV();
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return $"{Convert.ToBase64String(ivBytes)}|{Convert.ToBase64String(encBytes)}";
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if(_settings.Contains(AesKey))
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{
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return;
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}
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var key = App.Utilities.Crypto.RandomBytes(512 / 8);
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var encKey = RsaEncrypt(key);
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_settings.AddOrUpdateValue(AesKey, Convert.ToBase64String(encKey));
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}
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private byte[] AesDecrypt(string cipherString)
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private App.Models.SymmetricCryptoKey GetAesKey()
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{
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var parts = cipherString.Split('|');
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var ivBytes = Convert.FromBase64String(parts[0]);
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var encBytes = Convert.FromBase64String(parts[1]);
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try
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{
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var encKey = _settings.GetValueOrDefault<string>(AesKey);
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if(encKey == null)
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{
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return null;
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}
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var cipher = Cipher.GetInstance(AesMode);
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var spec = new GCMParameterSpec(128, ivBytes);
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cipher.Init(CipherMode.DecryptMode, GetAesKey(), spec);
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var decBytes = cipher.DoFinal(encBytes);
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return decBytes;
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var encKeyBytes = Convert.FromBase64String(encKey);
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var key = RsaDecrypt(encKeyBytes);
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return new App.Models.SymmetricCryptoKey(key);
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}
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catch
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{
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Console.WriteLine("Cannot get AesKey.");
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_keyStore.DeleteEntry(KeyAlias);
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_settings.Remove(AesKey);
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return null;
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}
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}
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private byte[] RsaEncrypt(byte[] input)
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@ -285,6 +285,7 @@
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<Compile Include="Pages\Vault\VaultEditLoginPage.cs" />
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<Compile Include="Pages\Vault\VaultListLoginsPage.cs" />
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<Compile Include="Services\PasswordGenerationService.cs" />
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<Compile Include="Utilities\Crypto.cs" />
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<Compile Include="Utilities\Helpers.cs" />
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<Compile Include="Utilities\IdentityHttpClient.cs" />
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<Compile Include="Utilities\Extentions.cs" />
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@ -10,6 +10,7 @@ using System.Collections.Generic;
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using Newtonsoft.Json;
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using Plugin.Settings.Abstractions;
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using Bit.App.Models.Api;
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using Bit.App.Utilities;
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namespace Bit.App.Services
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{
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@ -27,7 +28,6 @@ namespace Bit.App.Services
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private SymmetricCryptoKey _key;
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private SymmetricCryptoKey _encKey;
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private SymmetricCryptoKey _legacyEtmKey;
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private SymmetricCryptoKey _previousKey;
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private IDictionary<string, SymmetricCryptoKey> _orgKeys;
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private byte[] _privateKey;
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@ -257,14 +257,7 @@ namespace Bit.App.Services
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throw new ArgumentNullException(nameof(plainBytes));
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}
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var provider = WinRTCrypto.SymmetricKeyAlgorithmProvider.OpenAlgorithm(SymmetricAlgorithm.AesCbcPkcs7);
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var cryptoKey = provider.CreateSymmetricKey(key.EncKey);
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var iv = WinRTCrypto.CryptographicBuffer.GenerateRandom(provider.BlockLength);
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var encryptedBytes = WinRTCrypto.CryptographicEngine.Encrypt(cryptoKey, plainBytes, iv);
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var mac = key.MacKey != null ? ComputeMacBase64(encryptedBytes, iv, key.MacKey) : null;
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return new CipherString(key.EncryptionType, Convert.ToBase64String(iv),
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Convert.ToBase64String(encryptedBytes), mac);
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return Crypto.AesCbcEncrypt(plainBytes, key);
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}
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public string Decrypt(CipherString encyptedValue, SymmetricCryptoKey key = null)
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throw new ArgumentNullException(nameof(encyptedValue));
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}
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if(encyptedValue.EncryptionType == Enums.EncryptionType.AesCbc128_HmacSha256_B64 &&
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key.EncryptionType == Enums.EncryptionType.AesCbc256_B64)
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if(encyptedValue.EncryptionType == EncryptionType.AesCbc128_HmacSha256_B64 &&
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key.EncryptionType == EncryptionType.AesCbc256_B64)
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{
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// Old encrypt-then-mac scheme, swap out the key
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if(_legacyEtmKey == null)
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throw new ArgumentException("encType unavailable.");
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}
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if(key.MacKey != null && !string.IsNullOrWhiteSpace(encyptedValue.Mac))
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{
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var computedMacBytes = ComputeMac(encyptedValue.CipherTextBytes,
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encyptedValue.InitializationVectorBytes, key.MacKey);
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if(!MacsEqual(key.MacKey, computedMacBytes, encyptedValue.MacBytes))
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{
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throw new InvalidOperationException("MAC failed.");
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}
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}
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var provider = WinRTCrypto.SymmetricKeyAlgorithmProvider.OpenAlgorithm(SymmetricAlgorithm.AesCbcPkcs7);
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var cryptoKey = provider.CreateSymmetricKey(key.EncKey);
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var decryptedBytes = WinRTCrypto.CryptographicEngine.Decrypt(cryptoKey, encyptedValue.CipherTextBytes,
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encyptedValue.InitializationVectorBytes);
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return decryptedBytes;
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return Crypto.AesCbcDecrypt(encyptedValue, key);
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}
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public byte[] RsaDecryptToBytes(CipherString encyptedValue, byte[] privateKey)
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return decryptedBytes;
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}
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private string ComputeMacBase64(byte[] ctBytes, byte[] ivBytes, byte[] macKey)
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{
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var mac = ComputeMac(ctBytes, ivBytes, macKey);
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return Convert.ToBase64String(mac);
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}
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private byte[] ComputeMac(byte[] ctBytes, byte[] ivBytes, byte[] macKey)
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{
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if(macKey == null)
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{
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throw new ArgumentNullException(nameof(macKey));
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}
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if(ctBytes == null)
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{
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throw new ArgumentNullException(nameof(ctBytes));
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}
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if(ivBytes == null)
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{
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throw new ArgumentNullException(nameof(ivBytes));
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}
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var algorithm = WinRTCrypto.MacAlgorithmProvider.OpenAlgorithm(MacAlgorithm.HmacSha256);
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var hasher = algorithm.CreateHash(macKey);
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hasher.Append(ivBytes.Concat(ctBytes).ToArray());
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var mac = hasher.GetValueAndReset();
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return mac;
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}
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// Safely compare two MACs in a way that protects against timing attacks (Double HMAC Verification).
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// ref: https://www.nccgroup.trust/us/about-us/newsroom-and-events/blog/2011/february/double-hmac-verification/
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private bool MacsEqual(byte[] macKey, byte[] mac1, byte[] mac2)
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{
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var algorithm = WinRTCrypto.MacAlgorithmProvider.OpenAlgorithm(MacAlgorithm.HmacSha256);
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var hasher = algorithm.CreateHash(macKey);
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hasher.Append(mac1);
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mac1 = hasher.GetValueAndReset();
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hasher.Append(mac2);
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mac2 = hasher.GetValueAndReset();
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if(mac1.Length != mac2.Length)
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{
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return false;
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}
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for(int i = 0; i < mac2.Length; i++)
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{
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if(mac1[i] != mac2[i])
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{
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return false;
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}
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}
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return true;
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}
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public SymmetricCryptoKey MakeKeyFromPassword(string password, string salt)
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{
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if(password == null)
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@ -471,7 +391,7 @@ namespace Bit.App.Services
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public CipherString MakeEncKey(SymmetricCryptoKey key)
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{
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var bytes = WinRTCrypto.CryptographicBuffer.GenerateRandom(512 / 8);
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var bytes = Crypto.RandomBytes(512 / 8);
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return Encrypt(bytes, key);
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}
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}
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125
src/App/Utilities/Crypto.cs
Normal file
125
src/App/Utilities/Crypto.cs
Normal file
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@ -0,0 +1,125 @@
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using Bit.App.Models;
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using PCLCrypto;
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using System;
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using System.Linq;
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namespace Bit.App.Utilities
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{
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public static class Crypto
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{
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public static CipherString AesCbcEncrypt(byte[] plainBytes, SymmetricCryptoKey key)
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{
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if(key == null)
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{
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throw new ArgumentNullException(nameof(key));
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}
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if(plainBytes == null)
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{
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throw new ArgumentNullException(nameof(plainBytes));
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}
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var provider = WinRTCrypto.SymmetricKeyAlgorithmProvider.OpenAlgorithm(SymmetricAlgorithm.AesCbcPkcs7);
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var cryptoKey = provider.CreateSymmetricKey(key.EncKey);
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var iv = RandomBytes(provider.BlockLength);
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var encryptedBytes = WinRTCrypto.CryptographicEngine.Encrypt(cryptoKey, plainBytes, iv);
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var mac = key.MacKey != null ? ComputeMacBase64(encryptedBytes, iv, key.MacKey) : null;
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return new CipherString(key.EncryptionType, Convert.ToBase64String(iv),
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Convert.ToBase64String(encryptedBytes), mac);
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}
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public static byte[] AesCbcDecrypt(CipherString encyptedValue, SymmetricCryptoKey key)
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{
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if(key == null)
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{
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throw new ArgumentNullException(nameof(key));
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}
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if(encyptedValue == null)
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{
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throw new ArgumentNullException(nameof(encyptedValue));
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}
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if(key.MacKey != null && !string.IsNullOrWhiteSpace(encyptedValue.Mac))
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{
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var computedMacBytes = ComputeMac(encyptedValue.CipherTextBytes,
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encyptedValue.InitializationVectorBytes, key.MacKey);
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if(!MacsEqual(key.MacKey, computedMacBytes, encyptedValue.MacBytes))
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{
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throw new InvalidOperationException("MAC failed.");
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}
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}
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var provider = WinRTCrypto.SymmetricKeyAlgorithmProvider.OpenAlgorithm(SymmetricAlgorithm.AesCbcPkcs7);
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var cryptoKey = provider.CreateSymmetricKey(key.EncKey);
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var decryptedBytes = WinRTCrypto.CryptographicEngine.Decrypt(cryptoKey, encyptedValue.CipherTextBytes,
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encyptedValue.InitializationVectorBytes);
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return decryptedBytes;
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}
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public static byte[] RandomBytes(int length)
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{
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return WinRTCrypto.CryptographicBuffer.GenerateRandom(length);
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}
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private static string ComputeMacBase64(byte[] ctBytes, byte[] ivBytes, byte[] macKey)
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{
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var mac = ComputeMac(ctBytes, ivBytes, macKey);
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return Convert.ToBase64String(mac);
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}
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private static byte[] ComputeMac(byte[] ctBytes, byte[] ivBytes, byte[] macKey)
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{
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if(macKey == null)
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{
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throw new ArgumentNullException(nameof(macKey));
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}
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if(ctBytes == null)
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{
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throw new ArgumentNullException(nameof(ctBytes));
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}
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if(ivBytes == null)
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{
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throw new ArgumentNullException(nameof(ivBytes));
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}
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var algorithm = WinRTCrypto.MacAlgorithmProvider.OpenAlgorithm(MacAlgorithm.HmacSha256);
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var hasher = algorithm.CreateHash(macKey);
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hasher.Append(ivBytes.Concat(ctBytes).ToArray());
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var mac = hasher.GetValueAndReset();
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return mac;
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}
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// Safely compare two MACs in a way that protects against timing attacks (Double HMAC Verification).
|
||||
// ref: https://www.nccgroup.trust/us/about-us/newsroom-and-events/blog/2011/february/double-hmac-verification/
|
||||
private static bool MacsEqual(byte[] macKey, byte[] mac1, byte[] mac2)
|
||||
{
|
||||
var algorithm = WinRTCrypto.MacAlgorithmProvider.OpenAlgorithm(MacAlgorithm.HmacSha256);
|
||||
var hasher = algorithm.CreateHash(macKey);
|
||||
|
||||
hasher.Append(mac1);
|
||||
mac1 = hasher.GetValueAndReset();
|
||||
|
||||
hasher.Append(mac2);
|
||||
mac2 = hasher.GetValueAndReset();
|
||||
|
||||
if(mac1.Length != mac2.Length)
|
||||
{
|
||||
return false;
|
||||
}
|
||||
|
||||
for(int i = 0; i < mac2.Length; i++)
|
||||
{
|
||||
if(mac1[i] != mac2[i])
|
||||
{
|
||||
return false;
|
||||
}
|
||||
}
|
||||
|
||||
return true;
|
||||
}
|
||||
}
|
||||
}
|
Loading…
Reference in a new issue