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trezor-firmware/python/src/trezorlib/cosi.py
2020-09-29 11:30:40 +02:00

153 lines
5.4 KiB
Python

# This file is part of the Trezor project.
#
# Copyright (C) 2012-2019 SatoshiLabs and contributors
#
# This library is free software: you can redistribute it and/or modify
# it under the terms of the GNU Lesser General Public License version 3
# as published by the Free Software Foundation.
#
# This library 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 Lesser General Public License for more details.
#
# You should have received a copy of the License along with this library.
# If not, see <https://www.gnu.org/licenses/lgpl-3.0.html>.
from functools import reduce
from typing import Iterable, List, Tuple
from . import _ed25519, messages
from .tools import expect
# XXX, these could be NewType's, but that would infect users of the cosi module with these types as well.
# Unsure if we want that.
Ed25519PrivateKey = bytes
Ed25519PublicPoint = bytes
Ed25519Signature = bytes
def combine_keys(pks: Iterable[Ed25519PublicPoint]) -> Ed25519PublicPoint:
"""Combine a list of Ed25519 points into a "global" CoSi key."""
P = [_ed25519.decodepoint(pk) for pk in pks]
combine = reduce(_ed25519.edwards_add, P)
return Ed25519PublicPoint(_ed25519.encodepoint(combine))
def combine_sig(
global_R: Ed25519PublicPoint, sigs: Iterable[Ed25519Signature]
) -> Ed25519Signature:
"""Combine a list of signatures into a single CoSi signature."""
S = [_ed25519.decodeint(si) for si in sigs]
s = sum(S) % _ed25519.l
sig = global_R + _ed25519.encodeint(s)
return Ed25519Signature(sig)
def get_nonce(
sk: Ed25519PrivateKey, data: bytes, ctr: int = 0
) -> Tuple[int, Ed25519PublicPoint]:
"""Calculate CoSi nonces for given data.
These differ from Ed25519 deterministic nonces in that there is a counter appended at end.
Returns both the private point `r` and the partial signature `R`.
`r` is returned for performance reasons: :func:`sign_with_privkey`
takes it as its `nonce` argument so that it doesn't repeat the `get_nonce` call.
`R` should be combined with other partial signatures through :func:`combine_keys`
to obtain a "global commitment".
"""
# r = hash(hash(sk)[b .. 2b] + M + ctr)
# R = rB
h = _ed25519.H(sk)
bytesize = _ed25519.b // 8
assert len(h) == bytesize * 2
r = _ed25519.Hint(h[bytesize:] + data + ctr.to_bytes(4, "big"))
R = _ed25519.scalarmult(_ed25519.B, r)
return r, Ed25519PublicPoint(_ed25519.encodepoint(R))
def verify_combined(
signature: Ed25519Signature, digest: bytes, pub_key: Ed25519PublicPoint
) -> None:
"""Verify Ed25519 signature. Raise exception if the signature is invalid.
A CoSi combined signature is equivalent to a plain Ed25519 signature with a public
key that is a combination of the cosigners' public keys. This function takes the
combined public key and performs simple Ed25519 verification.
"""
# XXX this *might* change to bool function
_ed25519.checkvalid(signature, digest, pub_key)
def verify(
signature: Ed25519Signature,
digest: bytes,
sigs_required: int,
keys: List[Ed25519PublicPoint],
mask: int,
) -> None:
"""Verify a CoSi multi-signature. Raise exception if the signature is invalid.
This function verifies a M-of-N signature scheme. The arguments are:
- the minimum number M of signatures required
- public keys of all N possible cosigners
- a bitmask specifying which of the N cosigners have produced the signature.
The verification checks that the mask specifies at least M cosigners, then combines
the selected public keys and verifies the signature against the combined key.
"""
if sigs_required < 1:
raise ValueError("At least one signer must be specified.")
if mask.bit_length() > len(keys):
raise ValueError("Sigmask specifies more public keys than provided.")
selected_keys = [key for i, key in enumerate(keys) if mask & (1 << i)]
if len(selected_keys) < sigs_required:
raise _ed25519.SignatureMismatch("Insufficient number of signatures.")
global_pk = combine_keys(selected_keys)
return verify_combined(signature, digest, global_pk)
def pubkey_from_privkey(privkey: Ed25519PrivateKey) -> Ed25519PublicPoint:
"""Interpret 32 bytes of data as an Ed25519 private key.
Calculate and return the corresponding public key.
"""
return Ed25519PublicPoint(_ed25519.publickey_unsafe(privkey))
def sign_with_privkey(
digest: bytes,
privkey: Ed25519PrivateKey,
global_pubkey: Ed25519PublicPoint,
nonce: int,
global_commit: Ed25519PublicPoint,
) -> Ed25519Signature:
"""Create a CoSi signature of `digest` with the supplied private key.
This function needs to know the global public key and global commitment.
"""
h = _ed25519.H(privkey)
a = _ed25519.decodecoord(h)
S = (nonce + _ed25519.Hint(global_commit + global_pubkey + digest) * a) % _ed25519.l
return Ed25519Signature(_ed25519.encodeint(S))
# ====== Client functions ====== #
@expect(messages.CosiCommitment)
def commit(client, n, data):
return client.call(messages.CosiCommit(address_n=n, data=data))
@expect(messages.CosiSignature)
def sign(client, n, data, global_commitment, global_pubkey):
return client.call(
messages.CosiSign(
address_n=n,
data=data,
global_commitment=global_commitment,
global_pubkey=global_pubkey,
)
)