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Add OpenSSL 1.1 support to CryptMessage plugin by using radfish's pyelliptic version

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shortcutme 2019-08-02 16:13:54 +02:00
parent be742c78e7
commit fbafd23177
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11 changed files with 2169 additions and 4 deletions
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4
plugins/CryptMessage/CryptMessage.py
View file

@ -7,7 +7,7 @@ ecc_cache = {}
def eciesEncrypt(data, pubkey, ephemcurve=None, ciphername='aes-256-cbc'): def eciesEncrypt(data, pubkey, ephemcurve=None, ciphername='aes-256-cbc'):
import pyelliptic from lib import pyelliptic
pubkey_openssl = toOpensslPublickey(base64.b64decode(pubkey)) pubkey_openssl = toOpensslPublickey(base64.b64decode(pubkey))
curve, pubkey_x, pubkey_y, i = pyelliptic.ECC._decode_pubkey(pubkey_openssl) curve, pubkey_x, pubkey_y, i = pyelliptic.ECC._decode_pubkey(pubkey_openssl)
if ephemcurve is None: if ephemcurve is None:
@ -34,7 +34,7 @@ def split(encrypted):
def getEcc(privatekey=None): def getEcc(privatekey=None):
import pyelliptic from lib import pyelliptic
global ecc_cache global ecc_cache
if privatekey not in ecc_cache: if privatekey not in ecc_cache:
if privatekey: if privatekey:

4
plugins/CryptMessage/CryptMessagePlugin.py
View file

@ -60,7 +60,7 @@ class UiWebsocketPlugin(object):
# Encrypt a text using AES # Encrypt a text using AES
# Return: Iv, AES key, Encrypted text # Return: Iv, AES key, Encrypted text
def actionAesEncrypt(self, to, text, key=None, iv=None): def actionAesEncrypt(self, to, text, key=None, iv=None):
import pyelliptic from lib import pyelliptic
if key: if key:
key = base64.b64decode(key) key = base64.b64decode(key)
@ -83,7 +83,7 @@ class UiWebsocketPlugin(object):
# Decrypt a text using AES # Decrypt a text using AES
# Return: Decrypted text # Return: Decrypted text
def actionAesDecrypt(self, to, *args): def actionAesDecrypt(self, to, *args):
import pyelliptic from lib import pyelliptic
if len(args) == 3: # Single decrypt if len(args) == 3: # Single decrypt
encrypted_texts = [(args[0], args[1])] encrypted_texts = [(args[0], args[1])]

674
src/lib/pyelliptic/LICENSE Normal file
View file

@ -0,0 +1,674 @@
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copy of the Program in return for a fee.
END OF TERMS AND CONDITIONS
How to Apply These Terms to Your New Programs
If you develop a new program, and you want it to be of the greatest
possible use to the public, the best way to achieve this is to make it
free software which everyone can redistribute and change under these terms.
To do so, attach the following notices to the program. It is safest
to attach them to the start of each source file to most effectively
state the exclusion of warranty; and each file should have at least
the "copyright" line and a pointer to where the full notice is found.
<one line to give the program's name and a brief idea of what it does.>
Copyright (C) <year> <name of author>
This program is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>.
Also add information on how to contact you by electronic and paper mail.
If the program does terminal interaction, make it output a short
notice like this when it starts in an interactive mode:
<program> Copyright (C) <year> <name of author>
This program comes with ABSOLUTELY NO WARRANTY; for details type `show w'.
This is free software, and you are welcome to redistribute it
under certain conditions; type `show c' for details.
The hypothetical commands `show w' and `show c' should show the appropriate
parts of the General Public License. Of course, your program's commands
might be different; for a GUI interface, you would use an "about box".
You should also get your employer (if you work as a programmer) or school,
if any, to sign a "copyright disclaimer" for the program, if necessary.
For more information on this, and how to apply and follow the GNU GPL, see
<http://www.gnu.org/licenses/>.
The GNU General Public License does not permit incorporating your program
into proprietary programs. If your program is a subroutine library, you
may consider it more useful to permit linking proprietary applications with
the library. If this is what you want to do, use the GNU Lesser General
Public License instead of this License. But first, please read
<http://www.gnu.org/philosophy/why-not-lgpl.html>.

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# PyElliptic
PyElliptic is a high level wrapper for the cryptographic library : OpenSSL.
Under the GNU General Public License
Python3 compatible. For GNU/Linux and Windows.
Require OpenSSL
## Version
The [upstream pyelliptic](https://github.com/yann2192/pyelliptic) has been
deprecated by the author at 1.5.8 and ECC API has been removed.
This version is a fork of the pyelliptic extracted from the [BitMessage source
tree](https://github.com/Bitmessage/PyBitmessage), and does contain the ECC
API. To minimize confusion but to avoid renaming the module, major version has
been bumped.
BitMessage is actively maintained, and this fork of pyelliptic will track and
incorporate any changes to pyelliptic from BitMessage. Ideally, in the future,
BitMessage would import this module as a dependency instead of maintaining a
copy of the source in its repository.
The BitMessage fork forked from v1.3 of upstream pyelliptic. The commits in
this repository are the commits extracted from the BitMessage repository and
applied to pyelliptic v1.3 upstream repository (i.e. to the base of the fork),
so history with athorship is preserved.
Some of the changes in upstream pyelliptic between 1.3 and 1.5.8 came from
BitMessage, those changes are present in this fork. Other changes do not exist
in this fork (they may be added in the future).
Also, a few minor changes exist in this fork but is not (yet) present in
BitMessage source. See:
git log 1.3-PyBitmessage-37489cf7feff8d5047f24baa8f6d27f353a6d6ac..HEAD
## Features
### Asymmetric cryptography using Elliptic Curve Cryptography (ECC)
* Key agreement : ECDH
* Digital signatures : ECDSA
* Hybrid encryption : ECIES (like RSA)
### Symmetric cryptography
* AES-128 (CBC, OFB, CFB, CTR)
* AES-256 (CBC, OFB, CFB, CTR)
* Blowfish (CFB and CBC)
* RC4
### Other
* CSPRNG
* HMAC (using SHA512)
* PBKDF2 (SHA256 and SHA512)
## Example
```python
#!/usr/bin/python
import pyelliptic
# Symmetric encryption
iv = pyelliptic.Cipher.gen_IV('aes-256-cfb')
ctx = pyelliptic.Cipher("secretkey", iv, 1, ciphername='aes-256-cfb')
ciphertext = ctx.update('test1')
ciphertext += ctx.update('test2')
ciphertext += ctx.final()
ctx2 = pyelliptic.Cipher("secretkey", iv, 0, ciphername='aes-256-cfb')
print ctx2.ciphering(ciphertext)
# Asymmetric encryption
alice = pyelliptic.ECC() # default curve: sect283r1
bob = pyelliptic.ECC(curve='sect571r1')
ciphertext = alice.encrypt("Hello Bob", bob.get_pubkey())
print bob.decrypt(ciphertext)
signature = bob.sign("Hello Alice")
# alice's job :
print pyelliptic.ECC(pubkey=bob.get_pubkey()).verify(signature, "Hello Alice")
# ERROR !!!
try:
key = alice.get_ecdh_key(bob.get_pubkey())
except: print("For ECDH key agreement, the keys must be defined on the same curve !")
alice = pyelliptic.ECC(curve='sect571r1')
print alice.get_ecdh_key(bob.get_pubkey()).encode('hex')
print bob.get_ecdh_key(alice.get_pubkey()).encode('hex')
```

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# Copyright (C) 2010
# Author: Yann GUIBET
# Contact: <yannguibet@gmail.com>
__version__ = '1.3'
__all__ = [
'OpenSSL',
'ECC',
'Cipher',
'hmac_sha256',
'hmac_sha512',
'pbkdf2'
]
from .openssl import OpenSSL
from .ecc import ECC
from .cipher import Cipher
from .hash import hmac_sha256, hmac_sha512, pbkdf2

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# pylint: disable=missing-docstring,too-many-function-args
import hashlib
import re
P = 2**256 - 2**32 - 2**9 - 2**8 - 2**7 - 2**6 - 2**4 - 1
A = 0
Gx = 55066263022277343669578718895168534326250603453777594175500187360389116729240
Gy = 32670510020758816978083085130507043184471273380659243275938904335757337482424
G = (Gx, Gy)
def inv(a, n):
lm, hm = 1, 0
low, high = a % n, n
while low > 1:
r = high / low
nm, new = hm - lm * r, high - low * r
lm, low, hm, high = nm, new, lm, low
return lm % n
def get_code_string(base):
if base == 2:
return '01'
elif base == 10:
return '0123456789'
elif base == 16:
return "0123456789abcdef"
elif base == 58:
return "123456789ABCDEFGHJKLMNPQRSTUVWXYZabcdefghijkmnopqrstuvwxyz"
elif base == 256:
return ''.join([chr(x) for x in range(256)])
else:
raise ValueError("Invalid base!")
def encode(val, base, minlen=0):
code_string = get_code_string(base)
result = ""
while val > 0:
result = code_string[val % base] + result
val /= base
if len(result) < minlen:
result = code_string[0] * (minlen - len(result)) + result
return result
def decode(string, base):
code_string = get_code_string(base)
result = 0
if base == 16:
string = string.lower()
while string:
result *= base
result += code_string.find(string[0])
string = string[1:]
return result
def changebase(string, frm, to, minlen=0):
return encode(decode(string, frm), to, minlen)
def base10_add(a, b):
if a is None:
return b[0], b[1]
if b is None:
return a[0], a[1]
if a[0] == b[0]:
if a[1] == b[1]:
return base10_double(a[0], a[1])
return None
m = ((b[1] - a[1]) * inv(b[0] - a[0], P)) % P
x = (m * m - a[0] - b[0]) % P
y = (m * (a[0] - x) - a[1]) % P
return (x, y)
def base10_double(a):
if a is None:
return None
m = ((3 * a[0] * a[0] + A) * inv(2 * a[1], P)) % P
x = (m * m - 2 * a[0]) % P
y = (m * (a[0] - x) - a[1]) % P
return (x, y)
def base10_multiply(a, n):
if n == 0:
return G
if n == 1:
return a
if (n % 2) == 0:
return base10_double(base10_multiply(a, n / 2))
if (n % 2) == 1:
return base10_add(base10_double(base10_multiply(a, n / 2)), a)
return None
def hex_to_point(h):
return (decode(h[2:66], 16), decode(h[66:], 16))
def point_to_hex(p):
return '04' + encode(p[0], 16, 64) + encode(p[1], 16, 64)
def multiply(privkey, pubkey):
return point_to_hex(base10_multiply(hex_to_point(pubkey), decode(privkey, 16)))
def privtopub(privkey):
return point_to_hex(base10_multiply(G, decode(privkey, 16)))
def add(p1, p2):
if len(p1) == 32:
return encode(decode(p1, 16) + decode(p2, 16) % P, 16, 32)
return point_to_hex(base10_add(hex_to_point(p1), hex_to_point(p2)))
def hash_160(string):
intermed = hashlib.sha256(string).digest()
ripemd160 = hashlib.new('ripemd160')
ripemd160.update(intermed)
return ripemd160.digest()
def dbl_sha256(string):
return hashlib.sha256(hashlib.sha256(string).digest()).digest()
def bin_to_b58check(inp):
inp_fmtd = '\x00' + inp
leadingzbytes = len(re.match('^\x00*', inp_fmtd).group(0))
checksum = dbl_sha256(inp_fmtd)[:4]
return '1' * leadingzbytes + changebase(inp_fmtd + checksum, 256, 58)
# Convert a public key (in hex) to a Bitcoin address
def pubkey_to_address(pubkey):
return bin_to_b58check(hash_160(changebase(pubkey, 16, 256)))

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#!/usr/bin/env python
# -*- coding: utf-8 -*-
# Copyright (C) 2011 Yann GUIBET <yannguibet@gmail.com>
# See LICENSE for details.
from pyelliptic.openssl import OpenSSL
class Cipher:
"""
Symmetric encryption
import pyelliptic
iv = pyelliptic.Cipher.gen_IV('aes-256-cfb')
ctx = pyelliptic.Cipher("secretkey", iv, 1, ciphername='aes-256-cfb')
ciphertext = ctx.update('test1')
ciphertext += ctx.update('test2')
ciphertext += ctx.final()
ctx2 = pyelliptic.Cipher("secretkey", iv, 0, ciphername='aes-256-cfb')
print ctx2.ciphering(ciphertext)
"""
def __init__(self, key, iv, do, ciphername='aes-256-cbc'):
"""
do == 1 => Encrypt; do == 0 => Decrypt
"""
self.cipher = OpenSSL.get_cipher(ciphername)
self.ctx = OpenSSL.EVP_CIPHER_CTX_new()
if do == 1 or do == 0:
k = OpenSSL.malloc(key, len(key))
IV = OpenSSL.malloc(iv, len(iv))
OpenSSL.EVP_CipherInit_ex(
self.ctx, self.cipher.get_pointer(), 0, k, IV, do)
else:
raise Exception("RTFM ...")
@staticmethod
def get_all_cipher():
"""
static method, returns all ciphers available
"""
return OpenSSL.cipher_algo.keys()
@staticmethod
def get_blocksize(ciphername):
cipher = OpenSSL.get_cipher(ciphername)
return cipher.get_blocksize()
@staticmethod
def gen_IV(ciphername):
cipher = OpenSSL.get_cipher(ciphername)
return OpenSSL.rand(cipher.get_blocksize())
def update(self, input):
i = OpenSSL.c_int(0)
buffer = OpenSSL.malloc(b"", len(input) + self.cipher.get_blocksize())
inp = OpenSSL.malloc(input, len(input))
if OpenSSL.EVP_CipherUpdate(self.ctx, OpenSSL.byref(buffer),
OpenSSL.byref(i), inp, len(input)) == 0:
raise Exception("[OpenSSL] EVP_CipherUpdate FAIL ...")
return buffer.raw[0:i.value]
def final(self):
i = OpenSSL.c_int(0)
buffer = OpenSSL.malloc(b"", self.cipher.get_blocksize())
if (OpenSSL.EVP_CipherFinal_ex(self.ctx, OpenSSL.byref(buffer),
OpenSSL.byref(i))) == 0:
raise Exception("[OpenSSL] EVP_CipherFinal_ex FAIL ...")
return buffer.raw[0:i.value]
def ciphering(self, input):
"""
Do update and final in one method
"""
buff = self.update(input)
return buff + self.final()
def __del__(self):
if OpenSSL._hexversion > 0x10100000 and not OpenSSL._libreSSL:
OpenSSL.EVP_CIPHER_CTX_reset(self.ctx)
else:
OpenSSL.EVP_CIPHER_CTX_cleanup(self.ctx)
OpenSSL.EVP_CIPHER_CTX_free(self.ctx)

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#!/usr/bin/env python
# -*- coding: utf-8 -*-
"""
pyelliptic/ecc.py
=====================
"""
# pylint: disable=protected-access
# Copyright (C) 2011 Yann GUIBET <yannguibet@gmail.com>
# See LICENSE for details.
from hashlib import sha512
from struct import pack, unpack
from pyelliptic.cipher import Cipher
from pyelliptic.hash import equals, hmac_sha256
from pyelliptic.openssl import OpenSSL
class ECC(object):
"""
Asymmetric encryption with Elliptic Curve Cryptography (ECC)
ECDH, ECDSA and ECIES
>>> import pyelliptic
>>> alice = pyelliptic.ECC() # default curve: sect283r1
>>> bob = pyelliptic.ECC(curve='sect571r1')
>>> ciphertext = alice.encrypt("Hello Bob", bob.get_pubkey())
>>> print bob.decrypt(ciphertext)
>>> signature = bob.sign("Hello Alice")
>>> # alice's job :
>>> print pyelliptic.ECC(
>>> pubkey=bob.get_pubkey()).verify(signature, "Hello Alice")
>>> # ERROR !!!
>>> try:
>>> key = alice.get_ecdh_key(bob.get_pubkey())
>>> except:
>>> print("For ECDH key agreement, the keys must be defined on the same curve !")
>>> alice = pyelliptic.ECC(curve='sect571r1')
>>> print alice.get_ecdh_key(bob.get_pubkey()).encode('hex')
>>> print bob.get_ecdh_key(alice.get_pubkey()).encode('hex')
"""
def __init__(
self,
pubkey=None,
privkey=None,
pubkey_x=None,
pubkey_y=None,
raw_privkey=None,
curve='sect283r1',
): # pylint: disable=too-many-arguments
"""
For a normal and High level use, specifie pubkey,
privkey (if you need) and the curve
"""
if isinstance(curve, str):
self.curve = OpenSSL.get_curve(curve)
else:
self.curve = curve
if pubkey_x is not None and pubkey_y is not None:
self._set_keys(pubkey_x, pubkey_y, raw_privkey)
elif pubkey is not None:
curve, pubkey_x, pubkey_y, _ = ECC._decode_pubkey(pubkey)
if privkey is not None:
curve2, raw_privkey, _ = ECC._decode_privkey(privkey)
if curve != curve2:
raise Exception("Bad ECC keys ...")
self.curve = curve
self._set_keys(pubkey_x, pubkey_y, raw_privkey)
else:
self.privkey, self.pubkey_x, self.pubkey_y = self._generate()
def _set_keys(self, pubkey_x, pubkey_y, privkey):
if self.raw_check_key(privkey, pubkey_x, pubkey_y) < 0:
self.pubkey_x = None
self.pubkey_y = None
self.privkey = None
raise Exception("Bad ECC keys ...")
else:
self.pubkey_x = pubkey_x
self.pubkey_y = pubkey_y
self.privkey = privkey
@staticmethod
def get_curves():
"""
static method, returns the list of all the curves available
"""
return OpenSSL.curves.keys()
def get_curve(self):
"""Encryption object from curve name"""
return OpenSSL.get_curve_by_id(self.curve)
def get_curve_id(self):
"""Currently used curve"""
return self.curve
def get_pubkey(self):
"""
High level function which returns :
curve(2) + len_of_pubkeyX(2) + pubkeyX + len_of_pubkeyY + pubkeyY
"""
return b''.join((
pack('!H', self.curve),
pack('!H', len(self.pubkey_x)),
self.pubkey_x,
pack('!H', len(self.pubkey_y)),
self.pubkey_y,
))
def get_privkey(self):
"""
High level function which returns
curve(2) + len_of_privkey(2) + privkey
"""
return b''.join((
pack('!H', self.curve),
pack('!H', len(self.privkey)),
self.privkey,
))
@staticmethod
def _decode_pubkey(pubkey):
i = 0
curve = unpack('!H', pubkey[i:i + 2])[0]
i += 2
tmplen = unpack('!H', pubkey[i:i + 2])[0]
i += 2
pubkey_x = pubkey[i:i + tmplen]
i += tmplen
tmplen = unpack('!H', pubkey[i:i + 2])[0]
i += 2
pubkey_y = pubkey[i:i + tmplen]
i += tmplen
return curve, pubkey_x, pubkey_y, i
@staticmethod
def _decode_privkey(privkey):
i = 0
curve = unpack('!H', privkey[i:i + 2])[0]
i += 2
tmplen = unpack('!H', privkey[i:i + 2])[0]
i += 2
privkey = privkey[i:i + tmplen]
i += tmplen
return curve, privkey, i
def _generate(self):
try:
pub_key_x = OpenSSL.BN_new()
pub_key_y = OpenSSL.BN_new()
key = OpenSSL.EC_KEY_new_by_curve_name(self.curve)
if key == 0:
raise Exception("[OpenSSL] EC_KEY_new_by_curve_name FAIL ...")
if (OpenSSL.EC_KEY_generate_key(key)) == 0:
raise Exception("[OpenSSL] EC_KEY_generate_key FAIL ...")
if (OpenSSL.EC_KEY_check_key(key)) == 0:
raise Exception("[OpenSSL] EC_KEY_check_key FAIL ...")
priv_key = OpenSSL.EC_KEY_get0_private_key(key)
group = OpenSSL.EC_KEY_get0_group(key)
pub_key = OpenSSL.EC_KEY_get0_public_key(key)
if OpenSSL.EC_POINT_get_affine_coordinates_GFp(
group, pub_key, pub_key_x, pub_key_y, 0) == 0:
raise Exception("[OpenSSL] EC_POINT_get_affine_coordinates_GFp FAIL ...")
privkey = OpenSSL.malloc(0, OpenSSL.BN_num_bytes(priv_key))
pubkeyx = OpenSSL.malloc(0, OpenSSL.BN_num_bytes(pub_key_x))
pubkeyy = OpenSSL.malloc(0, OpenSSL.BN_num_bytes(pub_key_y))
OpenSSL.BN_bn2bin(priv_key, privkey)
privkey = privkey.raw
OpenSSL.BN_bn2bin(pub_key_x, pubkeyx)
pubkeyx = pubkeyx.raw
OpenSSL.BN_bn2bin(pub_key_y, pubkeyy)
pubkeyy = pubkeyy.raw
self.raw_check_key(privkey, pubkeyx, pubkeyy)
return privkey, pubkeyx, pubkeyy
finally:
OpenSSL.EC_KEY_free(key)
OpenSSL.BN_free(pub_key_x)
OpenSSL.BN_free(pub_key_y)
def get_ecdh_key(self, pubkey):
"""
High level function. Compute public key with the local private key
and returns a 512bits shared key
"""
curve, pubkey_x, pubkey_y, _ = ECC._decode_pubkey(pubkey)
if curve != self.curve:
raise Exception("ECC keys must be from the same curve !")
return sha512(self.raw_get_ecdh_key(pubkey_x, pubkey_y)).digest()
def raw_get_ecdh_key(self, pubkey_x, pubkey_y):
"""ECDH key as binary data"""
try:
ecdh_keybuffer = OpenSSL.malloc(0, 32)
other_key = OpenSSL.EC_KEY_new_by_curve_name(self.curve)
if other_key == 0:
raise Exception("[OpenSSL] EC_KEY_new_by_curve_name FAIL ...")
other_pub_key_x = OpenSSL.BN_bin2bn(pubkey_x, len(pubkey_x), 0)
other_pub_key_y = OpenSSL.BN_bin2bn(pubkey_y, len(pubkey_y), 0)
other_group = OpenSSL.EC_KEY_get0_group(other_key)
other_pub_key = OpenSSL.EC_POINT_new(other_group)
if (OpenSSL.EC_POINT_set_affine_coordinates_GFp(other_group,
other_pub_key,
other_pub_key_x,
other_pub_key_y,
0)) == 0:
raise Exception(
"[OpenSSL] EC_POINT_set_affine_coordinates_GFp FAIL ...")
if (OpenSSL.EC_KEY_set_public_key(other_key, other_pub_key)) == 0:
raise Exception("[OpenSSL] EC_KEY_set_public_key FAIL ...")
if (OpenSSL.EC_KEY_check_key(other_key)) == 0:
raise Exception("[OpenSSL] EC_KEY_check_key FAIL ...")
own_key = OpenSSL.EC_KEY_new_by_curve_name(self.curve)
if own_key == 0:
raise Exception("[OpenSSL] EC_KEY_new_by_curve_name FAIL ...")
own_priv_key = OpenSSL.BN_bin2bn(
self.privkey, len(self.privkey), 0)
if (OpenSSL.EC_KEY_set_private_key(own_key, own_priv_key)) == 0:
raise Exception("[OpenSSL] EC_KEY_set_private_key FAIL ...")
if OpenSSL._hexversion > 0x10100000 and not OpenSSL._libreSSL:
OpenSSL.EC_KEY_set_method(own_key, OpenSSL.EC_KEY_OpenSSL())
else:
OpenSSL.ECDH_set_method(own_key, OpenSSL.ECDH_OpenSSL())
ecdh_keylen = OpenSSL.ECDH_compute_key(
ecdh_keybuffer, 32, other_pub_key, own_key, 0)
if ecdh_keylen != 32:
raise Exception("[OpenSSL] ECDH keylen FAIL ...")
return ecdh_keybuffer.raw
finally:
OpenSSL.EC_KEY_free(other_key)
OpenSSL.BN_free(other_pub_key_x)
OpenSSL.BN_free(other_pub_key_y)
OpenSSL.EC_POINT_free(other_pub_key)
OpenSSL.EC_KEY_free(own_key)
OpenSSL.BN_free(own_priv_key)
def check_key(self, privkey, pubkey):
"""
Check the public key and the private key.
The private key is optional (replace by None)
"""
curve, pubkey_x, pubkey_y, _ = ECC._decode_pubkey(pubkey)
if privkey is None:
raw_privkey = None
curve2 = curve
else:
curve2, raw_privkey, _ = ECC._decode_privkey(privkey)
if curve != curve2:
raise Exception("Bad public and private key")
return self.raw_check_key(raw_privkey, pubkey_x, pubkey_y, curve)
def raw_check_key(self, privkey, pubkey_x, pubkey_y, curve=None):
"""Check key validity, key is supplied as binary data"""
# pylint: disable=too-many-branches
if curve is None:
curve = self.curve
elif isinstance(curve, str):
curve = OpenSSL.get_curve(curve)
else:
curve = curve
try:
key = OpenSSL.EC_KEY_new_by_curve_name(curve)
if key == 0:
raise Exception("[OpenSSL] EC_KEY_new_by_curve_name FAIL ...")
if privkey is not None:
priv_key = OpenSSL.BN_bin2bn(privkey, len(privkey), 0)
pub_key_x = OpenSSL.BN_bin2bn(pubkey_x, len(pubkey_x), 0)
pub_key_y = OpenSSL.BN_bin2bn(pubkey_y, len(pubkey_y), 0)
if privkey is not None:
if (OpenSSL.EC_KEY_set_private_key(key, priv_key)) == 0:
raise Exception(
"[OpenSSL] EC_KEY_set_private_key FAIL ...")
group = OpenSSL.EC_KEY_get0_group(key)
pub_key = OpenSSL.EC_POINT_new(group)
if (OpenSSL.EC_POINT_set_affine_coordinates_GFp(group, pub_key,
pub_key_x,
pub_key_y,
0)) == 0:
raise Exception(
"[OpenSSL] EC_POINT_set_affine_coordinates_GFp FAIL ...")
if (OpenSSL.EC_KEY_set_public_key(key, pub_key)) == 0:
raise Exception("[OpenSSL] EC_KEY_set_public_key FAIL ...")
if (OpenSSL.EC_KEY_check_key(key)) == 0:
raise Exception("[OpenSSL] EC_KEY_check_key FAIL ...")
return 0
finally:
OpenSSL.EC_KEY_free(key)
OpenSSL.BN_free(pub_key_x)
OpenSSL.BN_free(pub_key_y)
OpenSSL.EC_POINT_free(pub_key)
if privkey is not None:
OpenSSL.BN_free(priv_key)
def sign(self, inputb, digest_alg=OpenSSL.digest_ecdsa_sha1):
"""
Sign the input with ECDSA method and returns the signature
"""
# pylint: disable=too-many-branches,too-many-locals
try:
size = len(inputb)
buff = OpenSSL.malloc(inputb, size)
digest = OpenSSL.malloc(0, 64)
if OpenSSL._hexversion > 0x10100000 and not OpenSSL._libreSSL:
md_ctx = OpenSSL.EVP_MD_CTX_new()
else:
md_ctx = OpenSSL.EVP_MD_CTX_create()
dgst_len = OpenSSL.pointer(OpenSSL.c_int(0))
siglen = OpenSSL.pointer(OpenSSL.c_int(0))
sig = OpenSSL.malloc(0, 151)
key = OpenSSL.EC_KEY_new_by_curve_name(self.curve)
if key == 0:
raise Exception("[OpenSSL] EC_KEY_new_by_curve_name FAIL ...")
priv_key = OpenSSL.BN_bin2bn(self.privkey, len(self.privkey), 0)
pub_key_x = OpenSSL.BN_bin2bn(self.pubkey_x, len(self.pubkey_x), 0)
pub_key_y = OpenSSL.BN_bin2bn(self.pubkey_y, len(self.pubkey_y), 0)
if (OpenSSL.EC_KEY_set_private_key(key, priv_key)) == 0:
raise Exception("[OpenSSL] EC_KEY_set_private_key FAIL ...")
group = OpenSSL.EC_KEY_get0_group(key)
pub_key = OpenSSL.EC_POINT_new(group)
if (OpenSSL.EC_POINT_set_affine_coordinates_GFp(group, pub_key,
pub_key_x,
pub_key_y,
0)) == 0:
raise Exception(
"[OpenSSL] EC_POINT_set_affine_coordinates_GFp FAIL ...")
if (OpenSSL.EC_KEY_set_public_key(key, pub_key)) == 0:
raise Exception("[OpenSSL] EC_KEY_set_public_key FAIL ...")
if (OpenSSL.EC_KEY_check_key(key)) == 0:
raise Exception("[OpenSSL] EC_KEY_check_key FAIL ...")
if OpenSSL._hexversion > 0x10100000 and not OpenSSL._libreSSL:
OpenSSL.EVP_MD_CTX_new(md_ctx)
else:
OpenSSL.EVP_MD_CTX_init(md_ctx)
OpenSSL.EVP_DigestInit_ex(md_ctx, digest_alg(), None)
if (OpenSSL.EVP_DigestUpdate(md_ctx, buff, size)) == 0:
raise Exception("[OpenSSL] EVP_DigestUpdate FAIL ...")
OpenSSL.EVP_DigestFinal_ex(md_ctx, digest, dgst_len)
OpenSSL.ECDSA_sign(0, digest, dgst_len.contents, sig, siglen, key)
if (OpenSSL.ECDSA_verify(0, digest, dgst_len.contents, sig,
siglen.contents, key)) != 1:
raise Exception("[OpenSSL] ECDSA_verify FAIL ...")
return sig.raw[:siglen.contents.value]
finally:
OpenSSL.EC_KEY_free(key)
OpenSSL.BN_free(pub_key_x)
OpenSSL.BN_free(pub_key_y)
OpenSSL.BN_free(priv_key)
OpenSSL.EC_POINT_free(pub_key)
if OpenSSL._hexversion > 0x10100000 and not OpenSSL._libreSSL:
OpenSSL.EVP_MD_CTX_free(md_ctx)
else:
OpenSSL.EVP_MD_CTX_destroy(md_ctx)
def verify(self, sig, inputb, digest_alg=OpenSSL.digest_ecdsa_sha1):
"""
Verify the signature with the input and the local public key.
Returns a boolean
"""
# pylint: disable=too-many-branches
try:
bsig = OpenSSL.malloc(sig, len(sig))
binputb = OpenSSL.malloc(inputb, len(inputb))
digest = OpenSSL.malloc(0, 64)
dgst_len = OpenSSL.pointer(OpenSSL.c_int(0))
if OpenSSL._hexversion > 0x10100000 and not OpenSSL._libreSSL:
md_ctx = OpenSSL.EVP_MD_CTX_new()
else:
md_ctx = OpenSSL.EVP_MD_CTX_create()
key = OpenSSL.EC_KEY_new_by_curve_name(self.curve)
if key == 0:
raise Exception("[OpenSSL] EC_KEY_new_by_curve_name FAIL ...")
pub_key_x = OpenSSL.BN_bin2bn(self.pubkey_x, len(self.pubkey_x), 0)
pub_key_y = OpenSSL.BN_bin2bn(self.pubkey_y, len(self.pubkey_y), 0)
group = OpenSSL.EC_KEY_get0_group(key)
pub_key = OpenSSL.EC_POINT_new(group)
if (OpenSSL.EC_POINT_set_affine_coordinates_GFp(group, pub_key,
pub_key_x,
pub_key_y,
0)) == 0:
raise Exception(
"[OpenSSL] EC_POINT_set_affine_coordinates_GFp FAIL ...")
if (OpenSSL.EC_KEY_set_public_key(key, pub_key)) == 0:
raise Exception("[OpenSSL] EC_KEY_set_public_key FAIL ...")
if (OpenSSL.EC_KEY_check_key(key)) == 0:
raise Exception("[OpenSSL] EC_KEY_check_key FAIL ...")
if OpenSSL._hexversion > 0x10100000 and not OpenSSL._libreSSL:
OpenSSL.EVP_MD_CTX_new(md_ctx)
else:
OpenSSL.EVP_MD_CTX_init(md_ctx)
OpenSSL.EVP_DigestInit_ex(md_ctx, digest_alg(), None)
if (OpenSSL.EVP_DigestUpdate(md_ctx, binputb, len(inputb))) == 0:
raise Exception("[OpenSSL] EVP_DigestUpdate FAIL ...")
OpenSSL.EVP_DigestFinal_ex(md_ctx, digest, dgst_len)
ret = OpenSSL.ECDSA_verify(
0, digest, dgst_len.contents, bsig, len(sig), key)
if ret == -1:
return False # Fail to Check
if ret == 0:
return False # Bad signature !
return True # Good
finally:
OpenSSL.EC_KEY_free(key)
OpenSSL.BN_free(pub_key_x)
OpenSSL.BN_free(pub_key_y)
OpenSSL.EC_POINT_free(pub_key)
if OpenSSL._hexversion > 0x10100000 and not OpenSSL._libreSSL:
OpenSSL.EVP_MD_CTX_free(md_ctx)
else:
OpenSSL.EVP_MD_CTX_destroy(md_ctx)
@staticmethod
def encrypt(data, pubkey, ephemcurve=None, ciphername='aes-256-cbc'):
"""
Encrypt data with ECIES method using the public key of the recipient.
"""
curve, pubkey_x, pubkey_y, _ = ECC._decode_pubkey(pubkey)
return ECC.raw_encrypt(data, pubkey_x, pubkey_y, curve=curve,
ephemcurve=ephemcurve, ciphername=ciphername)
@staticmethod
def raw_encrypt(
data,
pubkey_x,
pubkey_y,
curve='sect283r1',
ephemcurve=None,
ciphername='aes-256-cbc',
): # pylint: disable=too-many-arguments
"""ECHD encryption, keys supplied in binary data format"""
if ephemcurve is None:
ephemcurve = curve
ephem = ECC(curve=ephemcurve)
key = sha512(ephem.raw_get_ecdh_key(pubkey_x, pubkey_y)).digest()
key_e, key_m = key[:32], key[32:]
pubkey = ephem.get_pubkey()
iv = OpenSSL.rand(OpenSSL.get_cipher(ciphername).get_blocksize())
ctx = Cipher(key_e, iv, 1, ciphername)
ciphertext = iv + pubkey + ctx.ciphering(data)
mac = hmac_sha256(key_m, ciphertext)
return ciphertext + mac
def decrypt(self, data, ciphername='aes-256-cbc'):
"""
Decrypt data with ECIES method using the local private key
"""
# pylint: disable=too-many-locals
blocksize = OpenSSL.get_cipher(ciphername).get_blocksize()
iv = data[:blocksize]
i = blocksize
_, pubkey_x, pubkey_y, i2 = ECC._decode_pubkey(data[i:])
i += i2
ciphertext = data[i:len(data) - 32]
i += len(ciphertext)
mac = data[i:]
key = sha512(self.raw_get_ecdh_key(pubkey_x, pubkey_y)).digest()
key_e, key_m = key[:32], key[32:]
if not equals(hmac_sha256(key_m, data[:len(data) - 32]), mac):
raise RuntimeError("Fail to verify data")
ctx = Cipher(key_e, iv, 0, ciphername)
return ctx.ciphering(ciphertext)

69
src/lib/pyelliptic/hash.py Normal file
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@ -0,0 +1,69 @@
#!/usr/bin/env python
# -*- coding: utf-8 -*-
# Copyright (C) 2011 Yann GUIBET <yannguibet@gmail.com>
# See LICENSE for details.
from pyelliptic.openssl import OpenSSL
# For python3
def _equals_bytes(a, b):
if len(a) != len(b):
return False
result = 0
for x, y in zip(a, b):
result |= x ^ y
return result == 0
def _equals_str(a, b):
if len(a) != len(b):
return False
result = 0
for x, y in zip(a, b):
result |= ord(x) ^ ord(y)
return result == 0
def equals(a, b):
if isinstance(a, str):
return _equals_str(a, b)
else:
return _equals_bytes(a, b)
def hmac_sha256(k, m):
"""
Compute the key and the message with HMAC SHA5256
"""
key = OpenSSL.malloc(k, len(k))
d = OpenSSL.malloc(m, len(m))
md = OpenSSL.malloc(0, 32)
i = OpenSSL.pointer(OpenSSL.c_int(0))
OpenSSL.HMAC(OpenSSL.EVP_sha256(), key, len(k), d, len(m), md, i)
return md.raw
def hmac_sha512(k, m):
"""
Compute the key and the message with HMAC SHA512
"""
key = OpenSSL.malloc(k, len(k))
d = OpenSSL.malloc(m, len(m))
md = OpenSSL.malloc(0, 64)
i = OpenSSL.pointer(OpenSSL.c_int(0))
OpenSSL.HMAC(OpenSSL.EVP_sha512(), key, len(k), d, len(m), md, i)
return md.raw
def pbkdf2(password, salt=None, i=10000, keylen=64):
if salt is None:
salt = OpenSSL.rand(8)
p_password = OpenSSL.malloc(password, len(password))
p_salt = OpenSSL.malloc(salt, len(salt))
output = OpenSSL.malloc(0, keylen)
OpenSSL.PKCS5_PBKDF2_HMAC(p_password, len(password), p_salt,
len(p_salt), i, OpenSSL.EVP_sha256(),
keylen, output)
return salt, output.raw

551
src/lib/pyelliptic/openssl.py Normal file
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#!/usr/bin/env python
# -*- coding: utf-8 -*-
# Copyright (C) 2011 Yann GUIBET <yannguibet@gmail.com>
# See LICENSE for details.
#
# Software slightly changed by Jonathan Warren <bitmessage at-symbol jonwarren.org>
import sys
import ctypes
OpenSSL = None
class CipherName:
def __init__(self, name, pointer, blocksize):
self._name = name
self._pointer = pointer
self._blocksize = blocksize
def __str__(self):
return "Cipher : " + self._name + " | Blocksize : " + str(self._blocksize) + " | Fonction pointer : " + str(self._pointer)
def get_pointer(self):
return self._pointer()
def get_name(self):
return self._name
def get_blocksize(self):
return self._blocksize
def get_version(library):
version = None
hexversion = None
cflags = None
try:
#OpenSSL 1.1
OPENSSL_VERSION = 0
OPENSSL_CFLAGS = 1
library.OpenSSL_version.argtypes = [ctypes.c_int]
library.OpenSSL_version.restype = ctypes.c_char_p
version = library.OpenSSL_version(OPENSSL_VERSION)
cflags = library.OpenSSL_version(OPENSSL_CFLAGS)
library.OpenSSL_version_num.restype = ctypes.c_long
hexversion = library.OpenSSL_version_num()
except AttributeError:
try:
#OpenSSL 1.0
SSLEAY_VERSION = 0
SSLEAY_CFLAGS = 2
library.SSLeay.restype = ctypes.c_long
library.SSLeay_version.restype = ctypes.c_char_p
library.SSLeay_version.argtypes = [ctypes.c_int]
version = library.SSLeay_version(SSLEAY_VERSION)
cflags = library.SSLeay_version(SSLEAY_CFLAGS)
hexversion = library.SSLeay()
except AttributeError:
#raise NotImplementedError('Cannot determine version of this OpenSSL library.')
pass
return (version, hexversion, cflags)
class _OpenSSL:
"""
Wrapper for OpenSSL using ctypes
"""
def __init__(self, library):
"""
Build the wrapper
"""
self._lib = ctypes.CDLL(library)
self._version, self._hexversion, self._cflags = get_version(self._lib)
self._libreSSL = self._version.startswith(b"LibreSSL")
self.pointer = ctypes.pointer
self.c_int = ctypes.c_int
self.byref = ctypes.byref
self.create_string_buffer = ctypes.create_string_buffer
self.BN_new = self._lib.BN_new
self.BN_new.restype = ctypes.c_void_p
self.BN_new.argtypes = []
self.BN_free = self._lib.BN_free
self.BN_free.restype = None
self.BN_free.argtypes = [ctypes.c_void_p]
self.BN_num_bits = self._lib.BN_num_bits
self.BN_num_bits.restype = ctypes.c_int
self.BN_num_bits.argtypes = [ctypes.c_void_p]
self.BN_bn2bin = self._lib.BN_bn2bin
self.BN_bn2bin.restype = ctypes.c_int
self.BN_bn2bin.argtypes = [ctypes.c_void_p, ctypes.c_void_p]
self.BN_bin2bn = self._lib.BN_bin2bn
self.BN_bin2bn.restype = ctypes.c_void_p
self.BN_bin2bn.argtypes = [ctypes.c_void_p, ctypes.c_int,
ctypes.c_void_p]
self.EC_KEY_free = self._lib.EC_KEY_free
self.EC_KEY_free.restype = None
self.EC_KEY_free.argtypes = [ctypes.c_void_p]
self.EC_KEY_new_by_curve_name = self._lib.EC_KEY_new_by_curve_name
self.EC_KEY_new_by_curve_name.restype = ctypes.c_void_p
self.EC_KEY_new_by_curve_name.argtypes = [ctypes.c_int]
self.EC_KEY_generate_key = self._lib.EC_KEY_generate_key
self.EC_KEY_generate_key.restype = ctypes.c_int
self.EC_KEY_generate_key.argtypes = [ctypes.c_void_p]
self.EC_KEY_check_key = self._lib.EC_KEY_check_key
self.EC_KEY_check_key.restype = ctypes.c_int
self.EC_KEY_check_key.argtypes = [ctypes.c_void_p]
self.EC_KEY_get0_private_key = self._lib.EC_KEY_get0_private_key
self.EC_KEY_get0_private_key.restype = ctypes.c_void_p
self.EC_KEY_get0_private_key.argtypes = [ctypes.c_void_p]
self.EC_KEY_get0_public_key = self._lib.EC_KEY_get0_public_key
self.EC_KEY_get0_public_key.restype = ctypes.c_void_p
self.EC_KEY_get0_public_key.argtypes = [ctypes.c_void_p]
self.EC_KEY_get0_group = self._lib.EC_KEY_get0_group
self.EC_KEY_get0_group.restype = ctypes.c_void_p
self.EC_KEY_get0_group.argtypes = [ctypes.c_void_p]
self.EC_POINT_get_affine_coordinates_GFp = self._lib.EC_POINT_get_affine_coordinates_GFp
self.EC_POINT_get_affine_coordinates_GFp.restype = ctypes.c_int
self.EC_POINT_get_affine_coordinates_GFp.argtypes = [ctypes.c_void_p, ctypes.c_void_p, ctypes.c_void_p, ctypes.c_void_p, ctypes.c_void_p]
self.EC_KEY_set_private_key = self._lib.EC_KEY_set_private_key
self.EC_KEY_set_private_key.restype = ctypes.c_int
self.EC_KEY_set_private_key.argtypes = [ctypes.c_void_p,
ctypes.c_void_p]
self.EC_KEY_set_public_key = self._lib.EC_KEY_set_public_key
self.EC_KEY_set_public_key.restype = ctypes.c_int
self.EC_KEY_set_public_key.argtypes = [ctypes.c_void_p,
ctypes.c_void_p]
self.EC_KEY_set_group = self._lib.EC_KEY_set_group
self.EC_KEY_set_group.restype = ctypes.c_int
self.EC_KEY_set_group.argtypes = [ctypes.c_void_p, ctypes.c_void_p]
self.EC_POINT_set_affine_coordinates_GFp = self._lib.EC_POINT_set_affine_coordinates_GFp
self.EC_POINT_set_affine_coordinates_GFp.restype = ctypes.c_int
self.EC_POINT_set_affine_coordinates_GFp.argtypes = [ctypes.c_void_p, ctypes.c_void_p, ctypes.c_void_p, ctypes.c_void_p, ctypes.c_void_p]
self.EC_POINT_new = self._lib.EC_POINT_new
self.EC_POINT_new.restype = ctypes.c_void_p
self.EC_POINT_new.argtypes = [ctypes.c_void_p]
self.EC_POINT_free = self._lib.EC_POINT_free
self.EC_POINT_free.restype = None
self.EC_POINT_free.argtypes = [ctypes.c_void_p]
self.BN_CTX_free = self._lib.BN_CTX_free
self.BN_CTX_free.restype = None
self.BN_CTX_free.argtypes = [ctypes.c_void_p]
self.EC_POINT_mul = self._lib.EC_POINT_mul
self.EC_POINT_mul.restype = ctypes.c_int
self.EC_POINT_mul.argtypes = [ctypes.c_void_p, ctypes.c_void_p, ctypes.c_void_p, ctypes.c_void_p, ctypes.c_void_p, ctypes.c_void_p]
self.EC_KEY_set_private_key = self._lib.EC_KEY_set_private_key
self.EC_KEY_set_private_key.restype = ctypes.c_int
self.EC_KEY_set_private_key.argtypes = [ctypes.c_void_p,
ctypes.c_void_p]
if self._hexversion >= 0x10100000 and not self._libreSSL:
self.EC_KEY_OpenSSL = self._lib.EC_KEY_OpenSSL
self._lib.EC_KEY_OpenSSL.restype = ctypes.c_void_p
self._lib.EC_KEY_OpenSSL.argtypes = []
self.EC_KEY_set_method = self._lib.EC_KEY_set_method
self._lib.EC_KEY_set_method.restype = ctypes.c_int
self._lib.EC_KEY_set_method.argtypes = [ctypes.c_void_p, ctypes.c_void_p]
else:
self.ECDH_OpenSSL = self._lib.ECDH_OpenSSL
self._lib.ECDH_OpenSSL.restype = ctypes.c_void_p
self._lib.ECDH_OpenSSL.argtypes = []
self.ECDH_set_method = self._lib.ECDH_set_method
self._lib.ECDH_set_method.restype = ctypes.c_int
self._lib.ECDH_set_method.argtypes = [ctypes.c_void_p, ctypes.c_void_p]
self.BN_CTX_new = self._lib.BN_CTX_new
self._lib.BN_CTX_new.restype = ctypes.c_void_p
self._lib.BN_CTX_new.argtypes = []
self.ECDH_compute_key = self._lib.ECDH_compute_key
self.ECDH_compute_key.restype = ctypes.c_int
self.ECDH_compute_key.argtypes = [ctypes.c_void_p,
ctypes.c_int, ctypes.c_void_p, ctypes.c_void_p]
self.EVP_CipherInit_ex = self._lib.EVP_CipherInit_ex
self.EVP_CipherInit_ex.restype = ctypes.c_int
self.EVP_CipherInit_ex.argtypes = [ctypes.c_void_p,
ctypes.c_void_p, ctypes.c_void_p]
self.EVP_CIPHER_CTX_new = self._lib.EVP_CIPHER_CTX_new
self.EVP_CIPHER_CTX_new.restype = ctypes.c_void_p
self.EVP_CIPHER_CTX_new.argtypes = []
# Cipher
self.EVP_aes_128_cfb128 = self._lib.EVP_aes_128_cfb128
self.EVP_aes_128_cfb128.restype = ctypes.c_void_p
self.EVP_aes_128_cfb128.argtypes = []
self.EVP_aes_256_cfb128 = self._lib.EVP_aes_256_cfb128
self.EVP_aes_256_cfb128.restype = ctypes.c_void_p
self.EVP_aes_256_cfb128.argtypes = []
self.EVP_aes_128_cbc = self._lib.EVP_aes_128_cbc
self.EVP_aes_128_cbc.restype = ctypes.c_void_p
self.EVP_aes_128_cbc.argtypes = []
self.EVP_aes_256_cbc = self._lib.EVP_aes_256_cbc
self.EVP_aes_256_cbc.restype = ctypes.c_void_p
self.EVP_aes_256_cbc.argtypes = []
#self.EVP_aes_128_ctr = self._lib.EVP_aes_128_ctr
#self.EVP_aes_128_ctr.restype = ctypes.c_void_p
#self.EVP_aes_128_ctr.argtypes = []
#self.EVP_aes_256_ctr = self._lib.EVP_aes_256_ctr
#self.EVP_aes_256_ctr.restype = ctypes.c_void_p
#self.EVP_aes_256_ctr.argtypes = []
self.EVP_aes_128_ofb = self._lib.EVP_aes_128_ofb
self.EVP_aes_128_ofb.restype = ctypes.c_void_p
self.EVP_aes_128_ofb.argtypes = []
self.EVP_aes_256_ofb = self._lib.EVP_aes_256_ofb
self.EVP_aes_256_ofb.restype = ctypes.c_void_p
self.EVP_aes_256_ofb.argtypes = []
self.EVP_bf_cbc = self._lib.EVP_bf_cbc
self.EVP_bf_cbc.restype = ctypes.c_void_p
self.EVP_bf_cbc.argtypes = []
self.EVP_bf_cfb64 = self._lib.EVP_bf_cfb64
self.EVP_bf_cfb64.restype = ctypes.c_void_p
self.EVP_bf_cfb64.argtypes = []
self.EVP_rc4 = self._lib.EVP_rc4
self.EVP_rc4.restype = ctypes.c_void_p
self.EVP_rc4.argtypes = []
if self._hexversion >= 0x10100000 and not self._libreSSL:
self.EVP_CIPHER_CTX_reset = self._lib.EVP_CIPHER_CTX_reset
self.EVP_CIPHER_CTX_reset.restype = ctypes.c_int
self.EVP_CIPHER_CTX_reset.argtypes = [ctypes.c_void_p]
else:
self.EVP_CIPHER_CTX_cleanup = self._lib.EVP_CIPHER_CTX_cleanup
self.EVP_CIPHER_CTX_cleanup.restype = ctypes.c_int
self.EVP_CIPHER_CTX_cleanup.argtypes = [ctypes.c_void_p]
self.EVP_CIPHER_CTX_free = self._lib.EVP_CIPHER_CTX_free
self.EVP_CIPHER_CTX_free.restype = None
self.EVP_CIPHER_CTX_free.argtypes = [ctypes.c_void_p]
self.EVP_CipherUpdate = self._lib.EVP_CipherUpdate
self.EVP_CipherUpdate.restype = ctypes.c_int
self.EVP_CipherUpdate.argtypes = [ctypes.c_void_p,
ctypes.c_void_p, ctypes.c_void_p, ctypes.c_void_p, ctypes.c_int]
self.EVP_CipherFinal_ex = self._lib.EVP_CipherFinal_ex
self.EVP_CipherFinal_ex.restype = ctypes.c_int
self.EVP_CipherFinal_ex.argtypes = [ctypes.c_void_p,
ctypes.c_void_p, ctypes.c_void_p]
self.EVP_DigestInit = self._lib.EVP_DigestInit
self.EVP_DigestInit.restype = ctypes.c_int
self._lib.EVP_DigestInit.argtypes = [ctypes.c_void_p, ctypes.c_void_p]
self.EVP_DigestInit_ex = self._lib.EVP_DigestInit_ex
self.EVP_DigestInit_ex.restype = ctypes.c_int
self._lib.EVP_DigestInit_ex.argtypes = 3 * [ctypes.c_void_p]
self.EVP_DigestUpdate = self._lib.EVP_DigestUpdate
self.EVP_DigestUpdate.restype = ctypes.c_int
self.EVP_DigestUpdate.argtypes = [ctypes.c_void_p,
ctypes.c_void_p, ctypes.c_int]
self.EVP_DigestFinal = self._lib.EVP_DigestFinal
self.EVP_DigestFinal.restype = ctypes.c_int
self.EVP_DigestFinal.argtypes = [ctypes.c_void_p,
ctypes.c_void_p, ctypes.c_void_p]
self.EVP_DigestFinal_ex = self._lib.EVP_DigestFinal_ex
self.EVP_DigestFinal_ex.restype = ctypes.c_int
self.EVP_DigestFinal_ex.argtypes = [ctypes.c_void_p,
ctypes.c_void_p, ctypes.c_void_p]
self.ECDSA_sign = self._lib.ECDSA_sign
self.ECDSA_sign.restype = ctypes.c_int
self.ECDSA_sign.argtypes = [ctypes.c_int, ctypes.c_void_p,
ctypes.c_int, ctypes.c_void_p, ctypes.c_void_p, ctypes.c_void_p]
self.ECDSA_verify = self._lib.ECDSA_verify
self.ECDSA_verify.restype = ctypes.c_int
self.ECDSA_verify.argtypes = [ctypes.c_int, ctypes.c_void_p,
ctypes.c_int, ctypes.c_void_p, ctypes.c_int, ctypes.c_void_p]
if self._hexversion >= 0x10100000 and not self._libreSSL:
self.EVP_MD_CTX_new = self._lib.EVP_MD_CTX_new
self.EVP_MD_CTX_new.restype = ctypes.c_void_p
self.EVP_MD_CTX_new.argtypes = []
self.EVP_MD_CTX_reset = self._lib.EVP_MD_CTX_reset
self.EVP_MD_CTX_reset.restype = None
self.EVP_MD_CTX_reset.argtypes = [ctypes.c_void_p]
self.EVP_MD_CTX_free = self._lib.EVP_MD_CTX_free
self.EVP_MD_CTX_free.restype = None
self.EVP_MD_CTX_free.argtypes = [ctypes.c_void_p]
self.EVP_sha1 = self._lib.EVP_sha1
self.EVP_sha1.restype = ctypes.c_void_p
self.EVP_sha1.argtypes = []
self.digest_ecdsa_sha1 = self.EVP_sha1
else:
self.EVP_MD_CTX_create = self._lib.EVP_MD_CTX_create
self.EVP_MD_CTX_create.restype = ctypes.c_void_p
self.EVP_MD_CTX_create.argtypes = []
self.EVP_MD_CTX_init = self._lib.EVP_MD_CTX_init
self.EVP_MD_CTX_init.restype = None
self.EVP_MD_CTX_init.argtypes = [ctypes.c_void_p]
self.EVP_MD_CTX_destroy = self._lib.EVP_MD_CTX_destroy
self.EVP_MD_CTX_destroy.restype = None
self.EVP_MD_CTX_destroy.argtypes = [ctypes.c_void_p]
self.EVP_ecdsa = self._lib.EVP_ecdsa
self._lib.EVP_ecdsa.restype = ctypes.c_void_p
self._lib.EVP_ecdsa.argtypes = []
self.digest_ecdsa_sha1 = self.EVP_ecdsa
self.RAND_bytes = self._lib.RAND_bytes
self.RAND_bytes.restype = ctypes.c_int
self.RAND_bytes.argtypes = [ctypes.c_void_p, ctypes.c_int]
self.EVP_sha256 = self._lib.EVP_sha256
self.EVP_sha256.restype = ctypes.c_void_p
self.EVP_sha256.argtypes = []
self.i2o_ECPublicKey = self._lib.i2o_ECPublicKey
self.i2o_ECPublicKey.restype = ctypes.c_int
self.i2o_ECPublicKey.argtypes = [ctypes.c_void_p, ctypes.c_void_p]
self.EVP_sha512 = self._lib.EVP_sha512
self.EVP_sha512.restype = ctypes.c_void_p
self.EVP_sha512.argtypes = []
self.HMAC = self._lib.HMAC
self.HMAC.restype = ctypes.c_void_p
self.HMAC.argtypes = [ctypes.c_void_p, ctypes.c_void_p, ctypes.c_int,
ctypes.c_void_p, ctypes.c_int, ctypes.c_void_p, ctypes.c_void_p]
try:
self.PKCS5_PBKDF2_HMAC = self._lib.PKCS5_PBKDF2_HMAC
except:
# The above is not compatible with all versions of OSX.
self.PKCS5_PBKDF2_HMAC = self._lib.PKCS5_PBKDF2_HMAC_SHA1
self.PKCS5_PBKDF2_HMAC.restype = ctypes.c_int
self.PKCS5_PBKDF2_HMAC.argtypes = [ctypes.c_void_p, ctypes.c_int,
ctypes.c_void_p, ctypes.c_int,
ctypes.c_int, ctypes.c_void_p,
ctypes.c_int, ctypes.c_void_p]
self._set_ciphers()
self._set_curves()
def _set_ciphers(self):
self.cipher_algo = {
'aes-128-cbc': CipherName('aes-128-cbc', self.EVP_aes_128_cbc, 16),
'aes-256-cbc': CipherName('aes-256-cbc', self.EVP_aes_256_cbc, 16),
'aes-128-cfb': CipherName('aes-128-cfb', self.EVP_aes_128_cfb128, 16),
'aes-256-cfb': CipherName('aes-256-cfb', self.EVP_aes_256_cfb128, 16),
'aes-128-ofb': CipherName('aes-128-ofb', self._lib.EVP_aes_128_ofb, 16),
'aes-256-ofb': CipherName('aes-256-ofb', self._lib.EVP_aes_256_ofb, 16),
#'aes-128-ctr': CipherName('aes-128-ctr', self._lib.EVP_aes_128_ctr, 16),
#'aes-256-ctr': CipherName('aes-256-ctr', self._lib.EVP_aes_256_ctr, 16),
'bf-cfb': CipherName('bf-cfb', self.EVP_bf_cfb64, 8),
'bf-cbc': CipherName('bf-cbc', self.EVP_bf_cbc, 8),
'rc4': CipherName('rc4', self.EVP_rc4, 128), # 128 is the initialisation size not block size
}
def _set_curves(self):
self.curves = {
'secp112r1': 704,
'secp112r2': 705,
'secp128r1': 706,
'secp128r2': 707,
'secp160k1': 708,
'secp160r1': 709,
'secp160r2': 710,
'secp192k1': 711,
'secp224k1': 712,
'secp224r1': 713,
'secp256k1': 714,
'secp384r1': 715,
'secp521r1': 716,
'sect113r1': 717,
'sect113r2': 718,
'sect131r1': 719,
'sect131r2': 720,
'sect163k1': 721,
'sect163r1': 722,
'sect163r2': 723,
'sect193r1': 724,
'sect193r2': 725,
'sect233k1': 726,
'sect233r1': 727,
'sect239k1': 728,
'sect283k1': 729,
'sect283r1': 730,
'sect409k1': 731,
'sect409r1': 732,
'sect571k1': 733,
'sect571r1': 734,
}
def BN_num_bytes(self, x):
"""
returns the length of a BN (OpenSSl API)
"""
return int((self.BN_num_bits(x) + 7) / 8)
def get_cipher(self, name):
"""
returns the OpenSSL cipher instance
"""
if name not in self.cipher_algo:
raise Exception("Unknown cipher")
return self.cipher_algo[name]
def get_curve(self, name):
"""
returns the id of a elliptic curve
"""
if name not in self.curves:
raise Exception("Unknown curve")
return self.curves[name]
def get_curve_by_id(self, id):
"""
returns the name of a elliptic curve with his id
"""
res = None
for i in self.curves:
if self.curves[i] == id:
res = i
break
if res is None:
raise Exception("Unknown curve")
return res
def rand(self, size):
"""
OpenSSL random function
"""
buffer = self.malloc(0, size)
# This pyelliptic library, by default, didn't check the return value of RAND_bytes. It is
# evidently possible that it returned an error and not-actually-random data. However, in
# tests on various operating systems, while generating hundreds of gigabytes of random
# strings of various sizes I could not get an error to occur. Also Bitcoin doesn't check
# the return value of RAND_bytes either.
# Fixed in Bitmessage version 0.4.2 (in source code on 2013-10-13)
while self.RAND_bytes(buffer, size) != 1:
import time
time.sleep(1)
return buffer.raw
def malloc(self, data, size):
"""
returns a create_string_buffer (ctypes)
"""
buffer = None
if data != 0:
if sys.version_info.major == 3 and isinstance(data, type('')):
data = data.encode()
buffer = self.create_string_buffer(data, size)
else:
buffer = self.create_string_buffer(size)
return buffer
def loadOpenSSL():
global OpenSSL
from os import path, environ
from ctypes.util import find_library
libdir = []
if getattr(sys,'frozen', None):
if 'darwin' in sys.platform:
libdir.extend([
path.join(environ['RESOURCEPATH'], '..', 'Frameworks','libcrypto.dylib'),
path.join(environ['RESOURCEPATH'], '..', 'Frameworks','libcrypto.1.1.0.dylib'),
path.join(environ['RESOURCEPATH'], '..', 'Frameworks','libcrypto.1.0.2.dylib'),
path.join(environ['RESOURCEPATH'], '..', 'Frameworks','libcrypto.1.0.1.dylib'),
path.join(environ['RESOURCEPATH'], '..', 'Frameworks','libcrypto.1.0.0.dylib'),
path.join(environ['RESOURCEPATH'], '..', 'Frameworks','libcrypto.0.9.8.dylib'),
])
elif 'win32' in sys.platform or 'win64' in sys.platform:
libdir.append(path.join(sys._MEIPASS, 'libeay32.dll'))
else:
libdir.extend([
path.join(sys._MEIPASS, 'libcrypto.so'),
path.join(sys._MEIPASS, 'libssl.so'),
path.join(sys._MEIPASS, 'libcrypto.so.1.1.0'),
path.join(sys._MEIPASS, 'libssl.so.1.1.0'),
path.join(sys._MEIPASS, 'libcrypto.so.1.0.2'),
path.join(sys._MEIPASS, 'libssl.so.1.0.2'),
path.join(sys._MEIPASS, 'libcrypto.so.1.0.1'),
path.join(sys._MEIPASS, 'libssl.so.1.0.1'),
path.join(sys._MEIPASS, 'libcrypto.so.1.0.0'),
path.join(sys._MEIPASS, 'libssl.so.1.0.0'),
path.join(sys._MEIPASS, 'libcrypto.so.0.9.8'),
path.join(sys._MEIPASS, 'libssl.so.0.9.8'),
])
if 'darwin' in sys.platform:
libdir.extend(['libcrypto.dylib', '/usr/local/opt/openssl/lib/libcrypto.dylib'])
elif 'win32' in sys.platform or 'win64' in sys.platform:
libdir.append('libeay32.dll')
else:
libdir.append('libcrypto.so')
libdir.append('libssl.so')
libdir.append('libcrypto.so.1.0.0')
libdir.append('libssl.so.1.0.0')
if 'linux' in sys.platform or 'darwin' in sys.platform or 'bsd' in sys.platform:
libdir.append(find_library('ssl'))
elif 'win32' in sys.platform or 'win64' in sys.platform:
libdir.append(find_library('libeay32'))
for library in libdir:
try:
OpenSSL = _OpenSSL(library)
return
except:
pass
raise Exception("Failed to load OpenSSL library, searched for: " + " ".join(libdir))
loadOpenSSL()

23
src/lib/pyelliptic/setup.py Normal file
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from setuptools import setup, find_packages
setup(
name="pyelliptic",
version='2.0.1',
url='https://github.com/radfish/pyelliptic',
license='GPL',
description="Python OpenSSL wrapper for ECC (ECDSA, ECIES), AES, HMAC, Blowfish, ...",
author='Yann GUIBET',
author_email='yannguibet@gmail.com',
maintainer="redfish",
maintainer_email='redfish@galactica.pw',
packages=find_packages(),
classifiers=[
'Operating System :: Unix',
'Operating System :: Microsoft :: Windows',
'Environment :: MacOS X',
'Programming Language :: Python',
'Programming Language :: Python :: 2.7',
'Programming Language :: Python :: 3.7',
'Topic :: Security :: Cryptography',
],
)