@Internal public class CryptoFunctions extends java.lang.Object
Constructor and Description |
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CryptoFunctions() |
Modifier and Type | Method and Description |
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static byte[] |
createXorArray1(java.lang.String password)
Creates an byte array for xor obfuscation (method 1)
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static int |
createXorKey1(java.lang.String password)
Create the xor key for xor obfuscation, which is used to create the xor array (method 1)
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static int |
createXorVerifier1(java.lang.String password)
Create the verifier for xor obfuscation (method 1)
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static int |
createXorVerifier2(java.lang.String password)
This method generates the xor verifier for word documents < 2007 (method 2).
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static byte[] |
generateIv(HashAlgorithm hashAlgorithm,
byte[] salt,
byte[] blockKey,
int blockSize)
2.3.4.12 Initialization Vector Generation (Agile Encryption)
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static byte[] |
generateKey(byte[] passwordHash,
HashAlgorithm hashAlgorithm,
byte[] blockKey,
int keySize)
2.3.4.11 Encryption Key Generation (Agile Encryption)
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static byte[] |
getBlock0(byte[] hash,
int size)
Returns a new byte array with a truncated to the given size.
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static javax.crypto.Cipher |
getCipher(java.security.Key key,
CipherAlgorithm cipherAlgorithm,
ChainingMode chain,
byte[] vec,
int cipherMode,
java.lang.String padding)
Initialize a new cipher object with the given cipher properties
If the given algorithm is not implemented in the JCE, it will try to load it from the bouncy castle
provider.
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static javax.crypto.Cipher |
getCipher(javax.crypto.SecretKey key,
CipherAlgorithm cipherAlgorithm,
ChainingMode chain,
byte[] vec,
int cipherMode)
Initialize a new cipher object with the given cipher properties and no padding
If the given algorithm is not implemented in the JCE, it will try to load it from the bouncy castle
provider.
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static javax.crypto.Mac |
getMac(HashAlgorithm hashAlgorithm) |
static java.security.MessageDigest |
getMessageDigest(HashAlgorithm hashAlgorithm) |
static byte[] |
hashPassword(java.lang.String password,
HashAlgorithm hashAlgorithm,
byte[] salt,
int spinCount)
2.3.4.7 ECMA-376 Document Encryption Key Generation (Standard Encryption)
2.3.4.11 Encryption Key Generation (Agile Encryption) |
static byte[] |
hashPassword(java.lang.String password,
HashAlgorithm hashAlgorithm,
byte[] salt,
int spinCount,
boolean iteratorFirst)
Generalized method for read and write protection hash generation.
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static void |
registerBouncyCastle() |
static java.lang.String |
xorHashPassword(java.lang.String password)
This method generates the xored-hashed password for word documents < 2007.
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static java.lang.String |
xorHashPasswordReversed(java.lang.String password)
Convenience function which returns the reversed xored-hashed password for further
processing in word documents 2007 and newer, which utilize a real hashing algorithm like sha1.
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public static byte[] hashPassword(java.lang.String password, HashAlgorithm hashAlgorithm, byte[] salt, int spinCount)
2.3.4.7 ECMA-376 Document Encryption Key Generation (Standard Encryption)
2.3.4.11 Encryption Key Generation (Agile Encryption)
The encryption key for ECMA-376 document encryption [ECMA-376] using agile encryption MUST be generated by using the following method, which is derived from PKCS #5: Password-Based Cryptography Version 2.0 [RFC2898].
Let H() be a hashing algorithm as determined by the PasswordKeyEncryptor.hashAlgorithm element, H_n be the hash data of the n-th iteration, and a plus sign (+) represent concatenation. The password MUST be provided as an array of Unicode characters. Limitations on the length of the password and the characters used by the password are implementation-dependent. The initial password hash is generated as follows:
H_0 = H(salt + password)
The salt used MUST be generated randomly. The salt MUST be stored in the PasswordKeyEncryptor.saltValue element contained within the \EncryptionInfo stream as specified in section 2.3.4.10. The hash is then iterated by using the following approach:
H_n = H(iterator + H_n-1)
where iterator is an unsigned 32-bit value that is initially set to 0x00000000 and then incremented monotonically on each iteration until PasswordKey.spinCount iterations have been performed. The value of iterator on the last iteration MUST be one less than PasswordKey.spinCount.
For POI, H_final will be calculated by generateKey(byte[],HashAlgorithm,byte[],int)
password
- hashAlgorithm
- salt
- spinCount
- public static byte[] hashPassword(java.lang.String password, HashAlgorithm hashAlgorithm, byte[] salt, int spinCount, boolean iteratorFirst)
password
- hashAlgorithm
- salt
- spinCount
- iteratorFirst
- if true, the iterator is hashed before the n-1 hash value,
if false the n-1 hash value is applied firstpublic static byte[] generateIv(HashAlgorithm hashAlgorithm, byte[] salt, byte[] blockKey, int blockSize)
2.3.4.12 Initialization Vector Generation (Agile Encryption)
Initialization vectors are used in all cases for agile encryption. An initialization vector MUST be generated by using the following method, where H() is a hash function that MUST be the same as specified in section 2.3.4.11 and a plus sign (+) represents concatenation:
blockKey: IV = H(KeySalt + blockKey)
KeySalt:IV = KeySalt
public static byte[] generateKey(byte[] passwordHash, HashAlgorithm hashAlgorithm, byte[] blockKey, int keySize)
2.3.4.11 Encryption Key Generation (Agile Encryption)
The final hash data that is used for an encryption key is then generated by using the following method:
H_final = H(H_n + blockKey)
where blockKey represents an array of bytes used to prevent two different blocks from encrypting to the same cipher text.
If the size of the resulting H_final is smaller than that of PasswordKeyEncryptor.keyBits, the key MUST be padded by appending bytes with a value of 0x36. If the hash value is larger in size than PasswordKeyEncryptor.keyBits, the key is obtained by truncating the hash value.
passwordHash
- hashAlgorithm
- blockKey
- keySize
- public static javax.crypto.Cipher getCipher(javax.crypto.SecretKey key, CipherAlgorithm cipherAlgorithm, ChainingMode chain, byte[] vec, int cipherMode)
key
- the secret keycipherAlgorithm
- the cipher algorithmchain
- the chaining modevec
- the initialization vector (IV), can be nullcipherMode
- Cipher.DECRYPT_MODE or Cipher.ENCRYPT_MODEjava.security.GeneralSecurityException
EncryptedDocumentException
- if the initialization failed or if an algorithm was specified,
which depends on a missing bouncy castle providerpublic static javax.crypto.Cipher getCipher(java.security.Key key, CipherAlgorithm cipherAlgorithm, ChainingMode chain, byte[] vec, int cipherMode, java.lang.String padding)
key
- the secret keycipherAlgorithm
- the cipher algorithmchain
- the chaining modevec
- the initialization vector (IV), can be nullcipherMode
- Cipher.DECRYPT_MODE or Cipher.ENCRYPT_MODEpadding
- the padding (null = NOPADDING, ANSIX923Padding, PKCS5Padding, PKCS7Padding, ISO10126Padding, ...)java.security.GeneralSecurityException
EncryptedDocumentException
- if the initialization failed or if an algorithm was specified,
which depends on a missing bouncy castle providerpublic static byte[] getBlock0(byte[] hash, int size)
hash
- the to be truncated/filled hash byte arraysize
- the size of the returned byte arraypublic static java.security.MessageDigest getMessageDigest(HashAlgorithm hashAlgorithm)
public static javax.crypto.Mac getMac(HashAlgorithm hashAlgorithm)
public static void registerBouncyCastle()
public static int createXorVerifier1(java.lang.String password)
password
- the passwordpublic static int createXorVerifier2(java.lang.String password)
password
- the passwordpublic static java.lang.String xorHashPassword(java.lang.String password)
public static java.lang.String xorHashPasswordReversed(java.lang.String password)
public static int createXorKey1(java.lang.String password)
password
- the passwordpublic static byte[] createXorArray1(java.lang.String password)
password
- the passwordCopyright 2018 The Apache Software Foundation or its licensors, as applicable.