ansible-later/env_27/lib/python2.7/site-packages/nacl/bindings/crypto_sign.py
2019-04-11 13:00:36 +02:00

286 lines
9.4 KiB
Python

# Copyright 2013 Donald Stufft and individual contributors
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
from __future__ import absolute_import, division, print_function
from nacl import exceptions as exc
from nacl._sodium import ffi, lib
from nacl.exceptions import ensure
crypto_sign_BYTES = lib.crypto_sign_bytes()
# crypto_sign_SEEDBYTES = lib.crypto_sign_seedbytes()
crypto_sign_SEEDBYTES = lib.crypto_sign_secretkeybytes() // 2
crypto_sign_PUBLICKEYBYTES = lib.crypto_sign_publickeybytes()
crypto_sign_SECRETKEYBYTES = lib.crypto_sign_secretkeybytes()
crypto_sign_curve25519_BYTES = lib.crypto_box_secretkeybytes()
crypto_sign_ed25519ph_STATEBYTES = lib.crypto_sign_ed25519ph_statebytes()
def crypto_sign_keypair():
"""
Returns a randomly generated public key and secret key.
:rtype: (bytes(public_key), bytes(secret_key))
"""
pk = ffi.new("unsigned char[]", crypto_sign_PUBLICKEYBYTES)
sk = ffi.new("unsigned char[]", crypto_sign_SECRETKEYBYTES)
rc = lib.crypto_sign_keypair(pk, sk)
ensure(rc == 0,
'Unexpected library error',
raising=exc.RuntimeError)
return (
ffi.buffer(pk, crypto_sign_PUBLICKEYBYTES)[:],
ffi.buffer(sk, crypto_sign_SECRETKEYBYTES)[:],
)
def crypto_sign_seed_keypair(seed):
"""
Computes and returns the public key and secret key using the seed ``seed``.
:param seed: bytes
:rtype: (bytes(public_key), bytes(secret_key))
"""
if len(seed) != crypto_sign_SEEDBYTES:
raise exc.ValueError("Invalid seed")
pk = ffi.new("unsigned char[]", crypto_sign_PUBLICKEYBYTES)
sk = ffi.new("unsigned char[]", crypto_sign_SECRETKEYBYTES)
rc = lib.crypto_sign_seed_keypair(pk, sk, seed)
ensure(rc == 0,
'Unexpected library error',
raising=exc.RuntimeError)
return (
ffi.buffer(pk, crypto_sign_PUBLICKEYBYTES)[:],
ffi.buffer(sk, crypto_sign_SECRETKEYBYTES)[:],
)
def crypto_sign(message, sk):
"""
Signs the message ``message`` using the secret key ``sk`` and returns the
signed message.
:param message: bytes
:param sk: bytes
:rtype: bytes
"""
signed = ffi.new("unsigned char[]", len(message) + crypto_sign_BYTES)
signed_len = ffi.new("unsigned long long *")
rc = lib.crypto_sign(signed, signed_len, message, len(message), sk)
ensure(rc == 0,
'Unexpected library error',
raising=exc.RuntimeError)
return ffi.buffer(signed, signed_len[0])[:]
def crypto_sign_open(signed, pk):
"""
Verifies the signature of the signed message ``signed`` using the public
key ``pk`` and returns the unsigned message.
:param signed: bytes
:param pk: bytes
:rtype: bytes
"""
message = ffi.new("unsigned char[]", len(signed))
message_len = ffi.new("unsigned long long *")
if lib.crypto_sign_open(
message, message_len, signed, len(signed), pk) != 0:
raise exc.BadSignatureError("Signature was forged or corrupt")
return ffi.buffer(message, message_len[0])[:]
def crypto_sign_ed25519_pk_to_curve25519(public_key_bytes):
"""
Converts a public Ed25519 key (encoded as bytes ``public_key_bytes``) to
a public Curve25519 key as bytes.
Raises a ValueError if ``public_key_bytes`` is not of length
``crypto_sign_PUBLICKEYBYTES``
:param public_key_bytes: bytes
:rtype: bytes
"""
if len(public_key_bytes) != crypto_sign_PUBLICKEYBYTES:
raise exc.ValueError("Invalid curve public key")
curve_public_key_len = crypto_sign_curve25519_BYTES
curve_public_key = ffi.new("unsigned char[]", curve_public_key_len)
rc = lib.crypto_sign_ed25519_pk_to_curve25519(curve_public_key,
public_key_bytes)
ensure(rc == 0,
'Unexpected library error',
raising=exc.RuntimeError)
return ffi.buffer(curve_public_key, curve_public_key_len)[:]
def crypto_sign_ed25519_sk_to_curve25519(secret_key_bytes):
"""
Converts a secret Ed25519 key (encoded as bytes ``secret_key_bytes``) to
a secret Curve25519 key as bytes.
Raises a ValueError if ``secret_key_bytes``is not of length
``crypto_sign_SECRETKEYBYTES``
:param public_key_bytes: bytes
:rtype: bytes
"""
if len(secret_key_bytes) != crypto_sign_SECRETKEYBYTES:
raise exc.ValueError("Invalid curve public key")
curve_secret_key_len = crypto_sign_curve25519_BYTES
curve_secret_key = ffi.new("unsigned char[]", curve_secret_key_len)
rc = lib.crypto_sign_ed25519_sk_to_curve25519(curve_secret_key,
secret_key_bytes)
ensure(rc == 0,
'Unexpected library error',
raising=exc.RuntimeError)
return ffi.buffer(curve_secret_key, curve_secret_key_len)[:]
class crypto_sign_ed25519ph_state(object):
"""
State object wrapping the sha-512 state used in ed25519ph computation
"""
__slots__ = ['state']
def __init__(self):
self.state = ffi.new('unsigned char[]',
crypto_sign_ed25519ph_STATEBYTES)
rc = lib.crypto_sign_ed25519ph_init(self.state)
ensure(rc == 0,
'Unexpected library error',
raising=exc.RuntimeError)
def crypto_sign_ed25519ph_update(edph, pmsg):
"""
Update the hash state wrapped in edph
:param edph: the ed25519ph state being updated
:type edph: crypto_sign_ed25519ph_state
:param pmsg: the partial message
:type pmsg: bytes
:rtype: None
"""
ensure(isinstance(edph, crypto_sign_ed25519ph_state),
'edph parameter must be a ed25519ph_state object',
raising=exc.TypeError)
ensure(isinstance(pmsg, bytes),
'pmsg parameter must be a bytes object',
raising=exc.TypeError)
rc = lib.crypto_sign_ed25519ph_update(edph.state,
pmsg,
len(pmsg))
ensure(rc == 0,
'Unexpected library error',
raising=exc.RuntimeError)
def crypto_sign_ed25519ph_final_create(edph,
sk):
"""
Create a signature for the data hashed in edph
using the secret key sk
:param edph: the ed25519ph state for the data
being signed
:type edph: crypto_sign_ed25519ph_state
:param sk: the ed25519 secret part of the signing key
:type sk: bytes
:return: ed25519ph signature
:rtype: bytes
"""
ensure(isinstance(edph, crypto_sign_ed25519ph_state),
'edph parameter must be a ed25519ph_state object',
raising=exc.TypeError)
ensure(isinstance(sk, bytes),
'secret key parameter must be a bytes object',
raising=exc.TypeError)
ensure(len(sk) == crypto_sign_SECRETKEYBYTES,
('secret key must be {0} '
'bytes long').format(crypto_sign_SECRETKEYBYTES),
raising=exc.TypeError)
signature = ffi.new("unsigned char[]", crypto_sign_BYTES)
rc = lib.crypto_sign_ed25519ph_final_create(edph.state,
signature,
ffi.NULL,
sk)
ensure(rc == 0,
'Unexpected library error',
raising=exc.RuntimeError)
return ffi.buffer(signature, crypto_sign_BYTES)[:]
def crypto_sign_ed25519ph_final_verify(edph,
signature,
pk):
"""
Verify a prehashed signature using the public key pk
:param edph: the ed25519ph state for the data
being verified
:type edph: crypto_sign_ed25519ph_state
:param signature: the signature being verified
:type signature: bytes
:param pk: the ed25519 public part of the signing key
:type pk: bytes
:return: True if the signature is valid
:rtype: boolean
:raises exc.BadSignatureError: if the signature is not valid
"""
ensure(isinstance(edph, crypto_sign_ed25519ph_state),
'edph parameter must be a ed25519ph_state object',
raising=exc.TypeError)
ensure(isinstance(signature, bytes),
'signature parameter must be a bytes object',
raising=exc.TypeError)
ensure(len(signature) == crypto_sign_BYTES,
('signature must be {0} '
'bytes long').format(crypto_sign_BYTES),
raising=exc.TypeError)
ensure(isinstance(pk, bytes),
'public key parameter must be a bytes object',
raising=exc.TypeError)
ensure(len(pk) == crypto_sign_PUBLICKEYBYTES,
('public key must be {0} '
'bytes long').format(crypto_sign_PUBLICKEYBYTES),
raising=exc.TypeError)
rc = lib.crypto_sign_ed25519ph_final_verify(edph.state,
signature,
pk)
if rc != 0:
raise exc.BadSignatureError("Signature was forged or corrupt")
return True