"""Abstract class for RSA.""" from cryptomath import * class RSAKey: """This is an abstract base class for RSA keys. Particular implementations of RSA keys, such as L{OpenSSL_RSAKey.OpenSSL_RSAKey}, L{Python_RSAKey.Python_RSAKey}, and L{PyCrypto_RSAKey.PyCrypto_RSAKey}, inherit from this. To create or parse an RSA key, don't use one of these classes directly. Instead, use the factory functions in L{tlslite.utils.keyfactory}. """ def __init__(self, n=0, e=0): """Create a new RSA key. If n and e are passed in, the new key will be initialized. @type n: int @param n: RSA modulus. @type e: int @param e: RSA public exponent. """ raise NotImplementedError() def __len__(self): """Return the length of this key in bits. @rtype: int """ return numBits(self.n) def hasPrivateKey(self): """Return whether or not this key has a private component. @rtype: bool """ raise NotImplementedError() def hash(self): """Return the cryptoID value corresponding to this key. @rtype: str """ raise NotImplementedError() def getSigningAlgorithm(self): """Return the cryptoID sigAlgo value corresponding to this key. @rtype: str """ return "pkcs1-sha1" def hashAndSign(self, bytes): """Hash and sign the passed-in bytes. This requires the key to have a private component. It performs a PKCS1-SHA1 signature on the passed-in data. @type bytes: str or L{array.array} of unsigned bytes @param bytes: The value which will be hashed and signed. @rtype: L{array.array} of unsigned bytes. @return: A PKCS1-SHA1 signature on the passed-in data. """ if not isinstance(bytes, type("")): bytes = bytesToString(bytes) hashBytes = stringToBytes(sha.sha(bytes).digest()) prefixedHashBytes = self._addPKCS1SHA1Prefix(hashBytes) sigBytes = self.sign(prefixedHashBytes) return sigBytes def hashAndVerify(self, sigBytes, bytes): """Hash and verify the passed-in bytes with the signature. This verifies a PKCS1-SHA1 signature on the passed-in data. @type sigBytes: L{array.array} of unsigned bytes @param sigBytes: A PKCS1-SHA1 signature. @type bytes: str or L{array.array} of unsigned bytes @param bytes: The value which will be hashed and verified. @rtype: bool @return: Whether the signature matches the passed-in data. """ if not isinstance(bytes, type("")): bytes = bytesToString(bytes) hashBytes = stringToBytes(sha.sha(bytes).digest()) prefixedHashBytes = self._addPKCS1SHA1Prefix(hashBytes) return self.verify(sigBytes, prefixedHashBytes) def sign(self, bytes): """Sign the passed-in bytes. This requires the key to have a private component. It performs a PKCS1 signature on the passed-in data. @type bytes: L{array.array} of unsigned bytes @param bytes: The value which will be signed. @rtype: L{array.array} of unsigned bytes. @return: A PKCS1 signature on the passed-in data. """ if not self.hasPrivateKey(): raise AssertionError() paddedBytes = self._addPKCS1Padding(bytes, 1) m = bytesToNumber(paddedBytes) if m >= self.n: raise ValueError() c = self._rawPrivateKeyOp(m) sigBytes = numberToBytes(c) return sigBytes def verify(self, sigBytes, bytes): """Verify the passed-in bytes with the signature. This verifies a PKCS1 signature on the passed-in data. @type sigBytes: L{array.array} of unsigned bytes @param sigBytes: A PKCS1 signature. @type bytes: L{array.array} of unsigned bytes @param bytes: The value which will be verified. @rtype: bool @return: Whether the signature matches the passed-in data. """ paddedBytes = self._addPKCS1Padding(bytes, 1) c = bytesToNumber(sigBytes) if c >= self.n: return False m = self._rawPublicKeyOp(c) checkBytes = numberToBytes(m) return checkBytes == paddedBytes def encrypt(self, bytes): """Encrypt the passed-in bytes. This performs PKCS1 encryption of the passed-in data. @type bytes: L{array.array} of unsigned bytes @param bytes: The value which will be encrypted. @rtype: L{array.array} of unsigned bytes. @return: A PKCS1 encryption of the passed-in data. """ paddedBytes = self._addPKCS1Padding(bytes, 2) m = bytesToNumber(paddedBytes) if m >= self.n: raise ValueError() c = self._rawPublicKeyOp(m) encBytes = numberToBytes(c) return encBytes def decrypt(self, encBytes): """Decrypt the passed-in bytes. This requires the key to have a private component. It performs PKCS1 decryption of the passed-in data. @type encBytes: L{array.array} of unsigned bytes @param encBytes: The value which will be decrypted. @rtype: L{array.array} of unsigned bytes or None. @return: A PKCS1 decryption of the passed-in data or None if the data is not properly formatted. """ if not self.hasPrivateKey(): raise AssertionError() c = bytesToNumber(encBytes) if c >= self.n: return None m = self._rawPrivateKeyOp(c) decBytes = numberToBytes(m) if (len(decBytes) != numBytes(self.n)-1): #Check first byte return None if decBytes[0] != 2: #Check second byte return None for x in range(len(decBytes)-1): #Scan through for zero separator if decBytes[x]== 0: break else: return None return decBytes[x+1:] #Return everything after the separator def _rawPrivateKeyOp(self, m): raise NotImplementedError() def _rawPublicKeyOp(self, c): raise NotImplementedError() def acceptsPassword(self): """Return True if the write() method accepts a password for use in encrypting the private key. @rtype: bool """ raise NotImplementedError() def write(self, password=None): """Return a string containing the key. @rtype: str @return: A string describing the key, in whichever format (PEM or XML) is native to the implementation. """ raise NotImplementedError() def writeXMLPublicKey(self, indent=''): """Return a string containing the key. @rtype: str @return: A string describing the public key, in XML format. """ return Python_RSAKey(self.n, self.e).write(indent) def generate(bits): """Generate a new key with the specified bit length. @rtype: L{tlslite.utils.RSAKey.RSAKey} """ raise NotImplementedError() generate = staticmethod(generate) # ************************************************************************** # Helper Functions for RSA Keys # ************************************************************************** def _addPKCS1SHA1Prefix(self, bytes): prefixBytes = createByteArraySequence(\ [48,33,48,9,6,5,43,14,3,2,26,5,0,4,20]) prefixedBytes = prefixBytes + bytes return prefixedBytes def _addPKCS1Padding(self, bytes, blockType): padLength = (numBytes(self.n) - (len(bytes)+3)) if blockType == 1: #Signature padding pad = [0xFF] * padLength elif blockType == 2: #Encryption padding pad = createByteArraySequence([]) while len(pad) < padLength: padBytes = getRandomBytes(padLength * 2) pad = [b for b in padBytes if b != 0] pad = pad[:padLength] else: raise AssertionError() #NOTE: To be proper, we should add [0,blockType]. However, #the zero is lost when the returned padding is converted #to a number, so we don't even bother with it. Also, #adding it would cause a misalignment in verify() padding = createByteArraySequence([blockType] + pad + [0]) paddedBytes = padding + bytes return paddedBytes