python-m2crypto 0.21.1-3 / usr / share / pyshared / M2Crypto / EVP.py

"""M2Crypto wrapper for OpenSSL EVP API.

Copyright (c) 1999-2004 Ng Pheng Siong. All rights reserved.

Portions Copyright (c) 2004-2007 Open Source Applications Foundation.
Author: Heikki Toivonen
"""

from M2Crypto import Err, util, BIO, RSA
import m2

class EVPError(Exception): pass

m2.evp_init(EVPError)


def pbkdf2(password, salt, iter, keylen):
    """
    Derive a key from password using PBKDF2 algorithm specified in RFC 2898.
    
    @param password: Derive the key from this password.
    @type password:  str
    @param salt:     Salt.
    @type salt:      str
    @param iter:     Number of iterations to perform.
    @type iter:      int 
    @param keylen:   Length of key to produce.
    @type keylen:    int
    @return:         Key.
    @rtype:          str
    """
    return m2.pkcs5_pbkdf2_hmac_sha1(password, salt, iter, keylen)

class MessageDigest:
    """
    Message Digest
    """
    m2_md_ctx_free = m2.md_ctx_free

    def __init__(self, algo):
        md = getattr(m2, algo, None)
        if md is None:
            raise ValueError, ('unknown algorithm', algo)
        self.md=md()
        self.ctx=m2.md_ctx_new()
        m2.digest_init(self.ctx, self.md)
        
    def __del__(self):
        if getattr(self, 'ctx', None):
            self.m2_md_ctx_free(self.ctx)

    def update(self, data):
        """
        Add data to be digested.
        
        @return: -1 for Python error, 1 for success, 0 for OpenSSL failure.
        """
        return m2.digest_update(self.ctx, data)

    def final(self):
        return m2.digest_final(self.ctx)

    # Deprecated.
    digest = final 


class HMAC:
    
    m2_hmac_ctx_free = m2.hmac_ctx_free

    def __init__(self, key, algo='sha1'):
        md = getattr(m2, algo, None)
        if md is None:
            raise ValueError, ('unknown algorithm', algo)
        self.md=md()
        self.ctx=m2.hmac_ctx_new()
        m2.hmac_init(self.ctx, key, self.md)
        
    def __del__(self):
        if getattr(self, 'ctx', None):
            self.m2_hmac_ctx_free(self.ctx)

    def reset(self, key):
        m2.hmac_init(self.ctx, key, self.md)

    def update(self, data):
        m2.hmac_update(self.ctx, data)

    def final(self):
        return m2.hmac_final(self.ctx)
    
    digest=final

def hmac(key, data, algo='sha1'):
    md = getattr(m2, algo, None)
    if md is None:
        raise ValueError, ('unknown algorithm', algo)
    return m2.hmac(key, data, md())


class Cipher:

    m2_cipher_ctx_free = m2.cipher_ctx_free

    def __init__(self, alg, key, iv, op, key_as_bytes=0, d='md5', salt='12345678', i=1, padding=1):
        cipher = getattr(m2, alg, None)
        if cipher is None:
            raise ValueError, ('unknown cipher', alg)
        self.cipher=cipher()
        if key_as_bytes:
            kmd = getattr(m2, d, None)
            if kmd is None:
                raise ValueError, ('unknown message digest', d)
            key = m2.bytes_to_key(self.cipher, kmd(), key, salt, iv, i)
        self.ctx=m2.cipher_ctx_new()
        m2.cipher_init(self.ctx, self.cipher, key, iv, op)
        self.set_padding(padding)
        del key
        
    def __del__(self):
        if getattr(self, 'ctx', None):        
            self.m2_cipher_ctx_free(self.ctx)

    def update(self, data):
        return m2.cipher_update(self.ctx, data)

    def final(self):
        return m2.cipher_final(self.ctx)

    def set_padding(self, padding=1):
        return m2.cipher_set_padding(self.ctx, padding) 


class PKey:
    """
    Public Key
    """
    
    m2_pkey_free = m2.pkey_free
    m2_md_ctx_free = m2.md_ctx_free

    def __init__(self, pkey=None, _pyfree=0, md='sha1'):
        if pkey is not None:
            self.pkey = pkey
            self._pyfree = _pyfree
        else:
            self.pkey = m2.pkey_new()
            self._pyfree = 1
        self._set_context(md)
        
    def __del__(self):
        if getattr(self, '_pyfree', 0):
            self.m2_pkey_free(self.pkey)
        if getattr(self, 'ctx', None):
            self.m2_md_ctx_free(self.ctx)

    def _ptr(self):
        return self.pkey

    def _set_context(self, md):
        mda = getattr(m2, md, None)
        if mda is None:
            raise ValueError, ('unknown message digest', md)
        self.md = mda()
        self.ctx = m2.md_ctx_new()

    def reset_context(self, md='sha1'):
        """
        Reset internal message digest context.

        @type md: string
        @param md: The message digest algorithm.
        """
        self._set_context(md)

    def sign_init(self):
        """
        Initialise signing operation with self.
        """
        m2.sign_init(self.ctx, self.md)

    def sign_update(self, data):
        """
        Feed data to signing operation.

        @type data: string
        @param data: Data to be signed.
        """
        m2.sign_update(self.ctx, data)

    def sign_final(self):
        """
        Return signature.

        @rtype: string
        @return: The signature.
        """
        return m2.sign_final(self.ctx, self.pkey)

    # Deprecated
    update = sign_update
    final = sign_final

    def verify_init(self):
        """
        Initialise signature verification operation with self.
        """
        m2.verify_init(self.ctx, self.md)

    def verify_update(self, data):
        """
        Feed data to verification operation.

        @type data: string
        @param data: Data to be verified.
        @return: -1 on Python error, 1 for success, 0 for OpenSSL error
        """
        return m2.verify_update(self.ctx, data)

    def verify_final(self, sign):
        """
        Return result of verification.

        @param sign: Signature to use for verification
        @rtype: int
        @return: Result of verification: 1 for success, 0 for failure, -1 on
                 other error.
        """
        return m2.verify_final(self.ctx, sign, self.pkey)

    def assign_rsa(self, rsa, capture=1):
        """
        Assign the RSA key pair to self.

        @type rsa: M2Crypto.RSA.RSA
        @param rsa: M2Crypto.RSA.RSA object to be assigned to self.

        @type capture:  boolean
        @param capture: If true (default), this PKey object will own the RSA
                        object, meaning that once the PKey object gets
                        deleted it is no longer safe to use the RSA object.
        
        @rtype: int
        @return: Return 1 for success and 0 for failure.
        """
        if capture:
            ret = m2.pkey_assign_rsa(self.pkey, rsa.rsa)
            if ret:
                rsa._pyfree = 0
        else:
            ret = m2.pkey_set1_rsa(self.pkey, rsa.rsa)
        return ret

    def get_rsa(self):
        """
        Return the underlying RSA key if that is what the EVP
        instance is holding.
        """
        rsa_ptr = m2.pkey_get1_rsa(self.pkey)
        if rsa_ptr is None:
            raise ValueError("PKey instance is not holding a RSA key")
        
        rsa = RSA.RSA_pub(rsa_ptr, 1)
        return rsa

    def save_key(self, file, cipher='aes_128_cbc', callback=util.passphrase_callback):
        """
        Save the key pair to a file in PEM format.

        @type file: string
        @param file: Name of file to save key to.

        @type cipher: string
        @param cipher: Symmetric cipher to protect the key. The default
        cipher is 'aes_128_cbc'. If cipher is None, then the key is saved
        in the clear.

        @type callback: Python callable
        @param callback: A Python callable object that is invoked
        to acquire a passphrase with which to protect the key. 
        The default is util.passphrase_callback.
        """
        bio = BIO.openfile(file, 'wb')
        return self.save_key_bio(bio, cipher, callback)

    def save_key_bio(self, bio, cipher='aes_128_cbc', callback=util.passphrase_callback):
        """
        Save the key pair to the M2Crypto.BIO object 'bio' in PEM format.

        @type bio: M2Crypto.BIO
        @param bio: M2Crypto.BIO object to save key to.

        @type cipher: string
        @param cipher: Symmetric cipher to protect the key. The default
        cipher is 'aes_128_cbc'. If cipher is None, then the key is saved
        in the clear.

        @type callback: Python callable
        @param callback: A Python callable object that is invoked
        to acquire a passphrase with which to protect the key. 
        The default is util.passphrase_callback.
        """
        if cipher is None:
            return m2.pkey_write_pem_no_cipher(self.pkey, bio._ptr(), callback)
        else:
            proto = getattr(m2, cipher, None)
            if proto is None:
                raise ValueError, 'no such cipher %s' % cipher
            return m2.pkey_write_pem(self.pkey, bio._ptr(), proto(), callback)

    def as_pem(self, cipher='aes_128_cbc', callback=util.passphrase_callback):
        """
        Return key in PEM format in a string.

        @type cipher: string
        @param cipher: Symmetric cipher to protect the key. The default
        cipher is 'aes_128_cbc'. If cipher is None, then the key is saved
        in the clear.

        @type callback: Python callable
        @param callback: A Python callable object that is invoked
        to acquire a passphrase with which to protect the key. 
        The default is util.passphrase_callback.
        """
        bio = BIO.MemoryBuffer()
        self.save_key_bio(bio, cipher, callback)
        return bio.read_all()

    def as_der(self):
        """
        Return key in DER format in a string
        """
        buf = m2.pkey_as_der(self.pkey)
        bio = BIO.MemoryBuffer(buf)
        return bio.read_all()
   
    def size(self):
        """
        Return the size of the key in bytes.
        """
        return m2.pkey_size(self.pkey)
        
    def get_modulus(self):
        """
        Return the modulus in hex format.
        """
        return m2.pkey_get_modulus(self.pkey)
   

def load_key(file, callback=util.passphrase_callback):
    """
    Load an M2Crypto.EVP.PKey from file.

    @type file: string
    @param file: Name of file containing the key in PEM format.

    @type callback: Python callable
    @param callback: A Python callable object that is invoked
    to acquire a passphrase with which to protect the key.

    @rtype: M2Crypto.EVP.PKey
    @return: M2Crypto.EVP.PKey object.
    """
    bio = m2.bio_new_file(file, 'r')
    if bio is None:
        raise BIO.BIOError(Err.get_error())
    cptr = m2.pkey_read_pem(bio, callback)
    m2.bio_free(bio)
    if cptr is None:
        raise EVPError(Err.get_error())
    return PKey(cptr, 1)

def load_key_bio(bio, callback=util.passphrase_callback):
    """
    Load an M2Crypto.EVP.PKey from an M2Crypto.BIO object.

    @type bio: M2Crypto.BIO
    @param bio: M2Crypto.BIO object containing the key in PEM format.

    @type callback: Python callable
    @param callback: A Python callable object that is invoked
    to acquire a passphrase with which to protect the key.

    @rtype: M2Crypto.EVP.PKey
    @return: M2Crypto.EVP.PKey object.
    """
    cptr = m2.pkey_read_pem(bio._ptr(), callback)
    if cptr is None:
        raise EVPError(Err.get_error())
    return PKey(cptr, 1)

def load_key_string(string, callback=util.passphrase_callback):
    """
    Load an M2Crypto.EVP.PKey from a string.

    @type string: string
    @param string: String containing the key in PEM format.

    @type callback: Python callable
    @param callback: A Python callable object that is invoked
    to acquire a passphrase with which to protect the key.

    @rtype: M2Crypto.EVP.PKey
    @return: M2Crypto.EVP.PKey object.
    """
    bio = BIO.MemoryBuffer(string)
    return load_key_bio( bio, callback)