protected internal static Cipher InitCipherForBlock(Cipher existing, int block, bool lastChunk, IEncryptionInfoBuilder builder, ISecretKey skey, int encryptionMode) { EncryptionHeader header = builder.GetHeader(); if (existing == null || lastChunk) { String pAdding = (lastChunk ? "PKCS5PAdding" : "NoPAdding"); existing = CryptoFunctions.GetCipher(skey, header.CipherAlgorithm, header.ChainingMode, header.KeySalt, encryptionMode, pAdding); } byte[] blockKey = new byte[4]; LittleEndian.PutInt(blockKey, 0, block); byte[] iv = CryptoFunctions.GenerateIv(header.HashAlgorithm, header.KeySalt, blockKey, header.BlockSize); AlgorithmParameterSpec aps; if (header.CipherAlgorithm == CipherAlgorithm.rc2) { aps = new RC2ParameterSpec(skey.GetEncoded().Length * 8, iv); } else { aps = new IvParameterSpec(iv); } existing.Init(encryptionMode, skey, aps); return(existing); }
protected internal static byte[] hashInput(IEncryptionInfoBuilder builder, byte[] pwHash, byte[] blockKey, byte[] inputKey, int cipherMode) { EncryptionVerifier ver = builder.GetVerifier(); AgileDecryptor dec = (AgileDecryptor)builder.GetDecryptor(); int keySize = dec.GetKeySizeInBytes(); int blockSize = dec.GetBlockSizeInBytes(); HashAlgorithm hashAlgo = ver.HashAlgorithm; byte[] salt = ver.Salt; byte[] intermedKey = CryptoFunctions.GenerateKey(pwHash, hashAlgo, blockKey, keySize); ISecretKey skey = new SecretKeySpec(intermedKey, ver.CipherAlgorithm.jceId); byte[] iv = CryptoFunctions.GenerateIv(hashAlgo, salt, null, blockSize); Cipher cipher = CryptoFunctions.GetCipher(skey, ver.CipherAlgorithm, ver.ChainingMode, iv, cipherMode); byte[] hashFinal; try { inputKey = CryptoFunctions.GetBlock0(inputKey, GetNextBlockSize(inputKey.Length, blockSize)); hashFinal = cipher.DoFinal(inputKey); return(hashFinal); } catch (Exception e) { throw new EncryptedDocumentException(e); } }
/** * instead of a password, it's also possible to decrypt via certificate. * Warning: this code is experimental and hasn't been validated * * @see <a href="http://social.msdn.microsoft.com/Forums/en-US/cc9092bb-0c82-4b5b-ae21-abf643bdb37c/agile-encryption-with-certificates">Agile encryption with certificates</a> * * @param keyPair * @param x509 * @return true, when the data can be successfully decrypted with the given private key * @throws GeneralSecurityException */ public bool VerifyPassword(KeyPair keyPair, X509Certificate x509) { AgileEncryptionVerifier ver = (AgileEncryptionVerifier)builder.GetVerifier(); AgileEncryptionHeader header = (AgileEncryptionHeader)builder.GetHeader(); HashAlgorithm hashAlgo = header.HashAlgorithm; CipherAlgorithm cipherAlgo = header.CipherAlgorithm; int blockSize = header.BlockSize; AgileCertificateEntry ace = null; foreach (AgileCertificateEntry aceEntry in ver.GetCertificates()) { if (x509.Equals(aceEntry.x509)) { ace = aceEntry; break; } } if (ace == null) { return(false); } Cipher cipher = Cipher.GetInstance("RSA"); cipher.Init(Cipher.DECRYPT_MODE, keyPair.getPrivate()); byte[] keyspec = cipher.DoFinal(ace.encryptedKey); SecretKeySpec secretKey = new SecretKeySpec(keyspec, ver.CipherAlgorithm.jceId); Mac x509Hmac = CryptoFunctions.GetMac(hashAlgo); x509Hmac.Init(secretKey); byte[] certVerifier = x509Hmac.DoFinal(ace.x509.GetEncoded()); byte[] vec = CryptoFunctions.GenerateIv(hashAlgo, header.KeySalt, kIntegrityKeyBlock, blockSize); cipher = GetCipher(secretKey, cipherAlgo, ver.ChainingMode, vec, Cipher.DECRYPT_MODE); byte[] hmacKey = cipher.DoFinal(header.GetEncryptedHmacKey()); hmacKey = GetBlock0(hmacKey, hashAlgo.hashSize); vec = CryptoFunctions.GenerateIv(hashAlgo, header.KeySalt, kIntegrityValueBlock, blockSize); cipher = GetCipher(secretKey, cipherAlgo, ver.ChainingMode, vec, Cipher.DECRYPT_MODE); byte[] hmacValue = cipher.DoFinal(header.GetEncryptedHmacValue()); hmacValue = GetBlock0(hmacValue, hashAlgo.hashSize); if (Arrays.Equals(ace.certVerifier, certVerifier)) { SetSecretKey(secretKey); SetIntegrityHmacKey(hmacKey); SetIntegrityHmacValue(hmacValue); return(true); } else { return(false); } }
/** * Generate an HMAC, as specified in [RFC2104], of the encrypted form of the data (message), * which the DataIntegrity element will verify by using the Salt generated in step 2 as the key. * Note that the entire EncryptedPackage stream (1), including the StreamSize field, MUST be * used as the message. * * Encrypt the HMAC as in step 3 by using a blockKey byte array consisting of the following bytes: * 0xa0, 0x67, 0x7f, 0x02, 0xb2, 0x2c, 0x84, and 0x33. **/ protected void UpdateIntegrityHMAC(FileInfo tmpFile, int oleStreamSize) { // as the integrity hmac needs to contain the StreamSize, // it's not possible to calculate it on-the-fly while buffering // TODO: add stream size parameter to GetDataStream() AgileEncryptionVerifier ver = builder.GetVerifier(); HashAlgorithm hashAlgo = ver.HashAlgorithm; Mac integrityMD = CryptoFunctions.GetMac(hashAlgo); integrityMD.Init(new SecretKeySpec(integritySalt, hashAlgo.jceHmacId)); byte[] buf = new byte[1024]; LittleEndian.PutLong(buf, 0, oleStreamSize); integrityMD.Update(buf, 0, LittleEndian.LONG_SIZE); FileStream fis = tmpFile.Create(); try { int readBytes; while ((readBytes = fis.Read(buf, 0, buf.Length)) > 0) { integrityMD.Update(buf, 0, readBytes); } } finally { fis.Close(); } byte[] hmacValue = integrityMD.DoFinal(); AgileEncryptionHeader header = builder.GetHeader(); int blockSize = header.BlockSize; byte[] iv = CryptoFunctions.GenerateIv(header.HashAlgorithm, header.KeySalt, AgileDecryptor.kIntegrityValueBlock, blockSize); Cipher cipher = CryptoFunctions.GetCipher(GetSecretKey(), header.CipherAlgorithm, header.ChainingMode, iv, Cipher.ENCRYPT_MODE); byte[] hmacValueFilled = GetBlock0(hmacValue, AgileDecryptor.GetNextBlockSize(hmacValue.Length, blockSize)); byte[] encryptedHmacValue = cipher.DoFinal(hmacValueFilled); header.SetEncryptedHmacValue(encryptedHmacValue); }
/** * Set decryption password */ public override bool VerifyPassword(String password) { AgileEncryptionVerifier ver = (AgileEncryptionVerifier)builder.GetVerifier(); AgileEncryptionHeader header = (AgileEncryptionHeader)builder.GetHeader(); HashAlgorithm hashAlgo = header.HashAlgorithm; CipherAlgorithm cipherAlgo = header.CipherAlgorithm; int blockSize = header.BlockSize; int keySize = header.KeySize / 8; byte[] pwHash = CryptoFunctions.HashPassword(password, ver.HashAlgorithm, ver.Salt, ver.SpinCount); /** * encryptedVerifierHashInput: This attribute MUST be generated by using the following steps: * 1. Generate a random array of bytes with the number of bytes used specified by the saltSize * attribute. * 2. Generate an encryption key as specified in section 2.3.4.11 by using the user-supplied password, * the binary byte array used to create the saltValue attribute, and a blockKey byte array * consisting of the following bytes: 0xfe, 0xa7, 0xd2, 0x76, 0x3b, 0x4b, 0x9e, and 0x79. * 3. Encrypt the random array of bytes generated in step 1 by using the binary form of the saltValue * attribute as an Initialization vector as specified in section 2.3.4.12. If the array of bytes is not an * integral multiple of blockSize bytes, pad the array with 0x00 to the next integral multiple of * blockSize bytes. * 4. Use base64 to encode the result of step 3. */ byte[] verfierInputEnc = hashInput(builder, pwHash, kVerifierInputBlock, ver.EncryptedVerifier, Cipher.DECRYPT_MODE); SetVerifier(verfierInputEnc); MessageDigest hashMD = CryptoFunctions.GetMessageDigest(hashAlgo); byte[] verifierHash = hashMD.Digest(verfierInputEnc); /** * encryptedVerifierHashValue: This attribute MUST be generated by using the following steps: * 1. Obtain the hash value of the random array of bytes generated in step 1 of the steps for * encryptedVerifierHashInput. * 2. Generate an encryption key as specified in section 2.3.4.11 by using the user-supplied password, * the binary byte array used to create the saltValue attribute, and a blockKey byte array * consisting of the following bytes: 0xd7, 0xaa, 0x0f, 0x6d, 0x30, 0x61, 0x34, and 0x4e. * 3. Encrypt the hash value obtained in step 1 by using the binary form of the saltValue attribute as * an Initialization vector as specified in section 2.3.4.12. If hashSize is not an integral multiple of * blockSize bytes, pad the hash value with 0x00 to an integral multiple of blockSize bytes. * 4. Use base64 to encode the result of step 3. */ byte[] verifierHashDec = hashInput(builder, pwHash, kHashedVerifierBlock, ver.EncryptedVerifierHash, Cipher.DECRYPT_MODE); verifierHashDec = CryptoFunctions.GetBlock0(verifierHashDec, hashAlgo.hashSize); /** * encryptedKeyValue: This attribute MUST be generated by using the following steps: * 1. Generate a random array of bytes that is the same size as specified by the * Encryptor.KeyData.keyBits attribute of the parent element. * 2. Generate an encryption key as specified in section 2.3.4.11, using the user-supplied password, * the binary byte array used to create the saltValue attribute, and a blockKey byte array * consisting of the following bytes: 0x14, 0x6e, 0x0b, 0xe7, 0xab, 0xac, 0xd0, and 0xd6. * 3. Encrypt the random array of bytes generated in step 1 by using the binary form of the saltValue * attribute as an Initialization vector as specified in section 2.3.4.12. If the array of bytes is not an * integral multiple of blockSize bytes, pad the array with 0x00 to an integral multiple of * blockSize bytes. * 4. Use base64 to encode the result of step 3. */ byte[] keyspec = hashInput(builder, pwHash, kCryptoKeyBlock, ver.EncryptedKey, Cipher.DECRYPT_MODE); keyspec = CryptoFunctions.GetBlock0(keyspec, keySize); SecretKeySpec secretKey = new SecretKeySpec(keyspec, ver.CipherAlgorithm.jceId); /** * 1. Obtain the intermediate key by decrypting the encryptedKeyValue from a KeyEncryptor * Contained within the KeyEncryptors sequence. Use this key for encryption operations in the * remaining steps of this section. * 2. Generate a random array of bytes, known as Salt, of the same length as the value of the * KeyData.HashSize attribute. * 3. Encrypt the random array of bytes generated in step 2 by using the binary form of the * KeyData.saltValue attribute and a blockKey byte array consisting of the following bytes: 0x5f, * 0xb2, 0xad, 0x01, 0x0c, 0xb9, 0xe1, and 0xf6 used to form an Initialization vector as specified in * section 2.3.4.12. If the array of bytes is not an integral multiple of blockSize bytes, pad the * array with 0x00 to the next integral multiple of blockSize bytes. * 4. Assign the encryptedHmacKey attribute to the base64-encoded form of the result of step 3. */ byte[] vec = CryptoFunctions.GenerateIv(hashAlgo, header.KeySalt, kIntegrityKeyBlock, blockSize); Cipher cipher = CryptoFunctions.GetCipher(secretKey, cipherAlgo, ver.ChainingMode, vec, Cipher.DECRYPT_MODE); byte[] hmacKey = cipher.DoFinal(header.GetEncryptedHmacKey()); hmacKey = CryptoFunctions.GetBlock0(hmacKey, hashAlgo.hashSize); /** * 5. Generate an HMAC, as specified in [RFC2104], of the encrypted form of the data (message), * which the DataIntegrity element will verify by using the Salt generated in step 2 as the key. * Note that the entire EncryptedPackage stream (1), including the StreamSize field, MUST be * used as the message. * 6. Encrypt the HMAC as in step 3 by using a blockKey byte array consisting of the following bytes: * 0xa0, 0x67, 0x7f, 0x02, 0xb2, 0x2c, 0x84, and 0x33. * 7. Assign the encryptedHmacValue attribute to the base64-encoded form of the result of step 6. */ vec = CryptoFunctions.GenerateIv(hashAlgo, header.KeySalt, kIntegrityValueBlock, blockSize); cipher = CryptoFunctions.GetCipher(secretKey, cipherAlgo, ver.ChainingMode, vec, Cipher.DECRYPT_MODE); byte[] hmacValue = cipher.DoFinal(header.GetEncryptedHmacValue()); hmacValue = CryptoFunctions.GetBlock0(hmacValue, hashAlgo.hashSize); if (Arrays.Equals(verifierHashDec, verifierHash)) { SetSecretKey(secretKey); SetIntegrityHmacKey(hmacKey); SetIntegrityHmacValue(hmacValue); return(true); } else { return(false); } }
public override void ConfirmPassword(String password, byte[] keySpec, byte[] keySalt, byte[] verifier, byte[] verifierSalt, byte[] integritySalt) { AgileEncryptionVerifier ver = builder.GetVerifier(); ver.Salt = (/*setter*/ verifierSalt); AgileEncryptionHeader header = builder.GetHeader(); header.KeySalt = (/*setter*/ keySalt); HashAlgorithm hashAlgo = ver.HashAlgorithm; int blockSize = header.BlockSize; pwHash = HashPassword(password, hashAlgo, verifierSalt, ver.SpinCount); /** * encryptedVerifierHashInput: This attribute MUST be generated by using the following steps: * 1. Generate a random array of bytes with the number of bytes used specified by the saltSize * attribute. * 2. Generate an encryption key as specified in section 2.3.4.11 by using the user-supplied password, * the binary byte array used to create the saltValue attribute, and a blockKey byte array * consisting of the following bytes: 0xfe, 0xa7, 0xd2, 0x76, 0x3b, 0x4b, 0x9e, and 0x79. * 3. Encrypt the random array of bytes generated in step 1 by using the binary form of the saltValue * attribute as an Initialization vector as specified in section 2.3.4.12. If the array of bytes is not an * integral multiple of blockSize bytes, pad the array with 0x00 to the next integral multiple of * blockSize bytes. * 4. Use base64 to encode the result of step 3. */ byte[] encryptedVerifier = AgileDecryptor.hashInput(builder, pwHash, AgileDecryptor.kVerifierInputBlock, verifier, Cipher.ENCRYPT_MODE); ver.EncryptedVerifier = (/*setter*/ encryptedVerifier); /** * encryptedVerifierHashValue: This attribute MUST be generated by using the following steps: * 1. Obtain the hash value of the random array of bytes generated in step 1 of the steps for * encryptedVerifierHashInput. * 2. Generate an encryption key as specified in section 2.3.4.11 by using the user-supplied password, * the binary byte array used to create the saltValue attribute, and a blockKey byte array * consisting of the following bytes: 0xd7, 0xaa, 0x0f, 0x6d, 0x30, 0x61, 0x34, and 0x4e. * 3. Encrypt the hash value obtained in step 1 by using the binary form of the saltValue attribute as * an Initialization vector as specified in section 2.3.4.12. If hashSize is not an integral multiple of * blockSize bytes, pad the hash value with 0x00 to an integral multiple of blockSize bytes. * 4. Use base64 to encode the result of step 3. */ MessageDigest hashMD = GetMessageDigest(hashAlgo); byte[] hashedVerifier = hashMD.Digest(verifier); byte[] encryptedVerifierHash = AgileDecryptor.hashInput(builder, pwHash, AgileDecryptor.kHashedVerifierBlock, hashedVerifier, Cipher.ENCRYPT_MODE); ver.EncryptedVerifierHash = (/*setter*/ encryptedVerifierHash); /** * encryptedKeyValue: This attribute MUST be generated by using the following steps: * 1. Generate a random array of bytes that is the same size as specified by the * Encryptor.KeyData.keyBits attribute of the parent element. * 2. Generate an encryption key as specified in section 2.3.4.11, using the user-supplied password, * the binary byte array used to create the saltValue attribute, and a blockKey byte array * consisting of the following bytes: 0x14, 0x6e, 0x0b, 0xe7, 0xab, 0xac, 0xd0, and 0xd6. * 3. Encrypt the random array of bytes generated in step 1 by using the binary form of the saltValue * attribute as an Initialization vector as specified in section 2.3.4.12. If the array of bytes is not an * integral multiple of blockSize bytes, pad the array with 0x00 to an integral multiple of * blockSize bytes. * 4. Use base64 to encode the result of step 3. */ byte[] encryptedKey = AgileDecryptor.hashInput(builder, pwHash, AgileDecryptor.kCryptoKeyBlock, keySpec, Cipher.ENCRYPT_MODE); ver.EncryptedKey = (/*setter*/ encryptedKey); ISecretKey secretKey = new SecretKeySpec(keySpec, ver.CipherAlgorithm.jceId); SetSecretKey(secretKey); /* * 2.3.4.14 DataIntegrity Generation (Agile Encryption) * * The DataIntegrity element Contained within an Encryption element MUST be generated by using * the following steps: * 1. Obtain the intermediate key by decrypting the encryptedKeyValue from a KeyEncryptor * Contained within the KeyEncryptors sequence. Use this key for encryption operations in the * remaining steps of this section. * 2. Generate a random array of bytes, known as Salt, of the same length as the value of the * KeyData.HashSize attribute. * 3. Encrypt the random array of bytes generated in step 2 by using the binary form of the * KeyData.saltValue attribute and a blockKey byte array consisting of the following bytes: * 0x5f, 0xb2, 0xad, 0x01, 0x0c, 0xb9, 0xe1, and 0xf6 used to form an Initialization vector as * specified in section 2.3.4.12. If the array of bytes is not an integral multiple of blockSize * bytes, pad the array with 0x00 to the next integral multiple of blockSize bytes. * 4. Assign the encryptedHmacKey attribute to the base64-encoded form of the result of step 3. * 5. Generate an HMAC, as specified in [RFC2104], of the encrypted form of the data (message), * which the DataIntegrity element will verify by using the Salt generated in step 2 as the key. * Note that the entire EncryptedPackage stream (1), including the StreamSize field, MUST be * used as the message. * 6. Encrypt the HMAC as in step 3 by using a blockKey byte array consisting of the following bytes: * 0xa0, 0x67, 0x7f, 0x02, 0xb2, 0x2c, 0x84, and 0x33. * 7. Assign the encryptedHmacValue attribute to the base64-encoded form of the result of step 6. */ this.integritySalt = integritySalt; try { byte[] vec = CryptoFunctions.GenerateIv(hashAlgo, header.KeySalt, AgileDecryptor.kIntegrityKeyBlock, header.BlockSize); Cipher cipher = GetCipher(secretKey, ver.CipherAlgorithm, ver.ChainingMode, vec, Cipher.ENCRYPT_MODE); byte[] FilledSalt = GetBlock0(integritySalt, AgileDecryptor.GetNextBlockSize(integritySalt.Length, blockSize)); byte[] encryptedHmacKey = cipher.DoFinal(FilledSalt); header.SetEncryptedHmacKey(encryptedHmacKey); cipher = Cipher.GetInstance("RSA"); foreach (AgileCertificateEntry ace in ver.GetCertificates()) { cipher.Init(Cipher.ENCRYPT_MODE, ace.x509.GetPublicKey()); ace.encryptedKey = cipher.DoFinal(GetSecretKey().GetEncoded()); Mac x509Hmac = CryptoFunctions.GetMac(hashAlgo); x509Hmac.Init(GetSecretKey()); ace.certVerifier = x509Hmac.DoFinal(ace.x509.GetEncoded()); } } catch (Exception e) { throw new EncryptedDocumentException(e); } }