1
0
mirror of https://github.com/trezor/trezor-firmware.git synced 2024-12-02 04:18:20 +00:00
trezor-firmware/tests/device_tests/bitcoin/payment_req.py

173 lines
6.0 KiB
Python
Raw Normal View History

from collections import namedtuple
from hashlib import sha256
from ecdsa import ECDH, SECP256k1, SigningKey
from trezorlib import btc, messages
from ...common import compact_size
SLIP44 = 1 # Testnet
TextMemo = namedtuple("TextMemo", "text")
RefundMemo = namedtuple("RefundMemo", "address_n")
CoinPurchaseMemo = namedtuple(
"CoinPurchaseMemo", "amount, coin_name, slip44, address_n"
)
payment_req_signer = SigningKey.from_string(
b"?S\ti\x8b\xc5o{,\xab\x03\x194\xea\xa8[_:\xeb\xdf\xce\xef\xe50\xf17D\x98`\xb9dj",
curve=SECP256k1,
)
def hash_bytes_prefixed(hasher, data):
hasher.update(compact_size(len(data)))
hasher.update(data)
def make_payment_request(
client, recipient_name, outputs, change_addresses=None, memos=None, nonce=None
):
h_pr = sha256(b"SL\x00\x24")
if nonce:
hash_bytes_prefixed(h_pr, nonce)
else:
h_pr.update(b"\0")
hash_bytes_prefixed(h_pr, recipient_name.encode())
if memos is None:
memos = []
h_pr.update(len(memos).to_bytes(1, "little"))
msg_memos = []
for memo in memos:
if isinstance(memo, TextMemo):
msg_memo = messages.TextMemo(text=memo.text)
msg_memos.append(messages.PaymentRequestMemo(text_memo=msg_memo))
memo_type = 1
h_pr.update(memo_type.to_bytes(4, "little"))
hash_bytes_prefixed(h_pr, memo.text.encode())
elif isinstance(memo, RefundMemo):
address_resp = btc.get_authenticated_address(
client, "Testnet", memo.address_n
)
msg_memo = messages.RefundMemo(
address=address_resp.address, mac=address_resp.mac
)
msg_memos.append(messages.PaymentRequestMemo(refund_memo=msg_memo))
memo_type = 2
h_pr.update(memo_type.to_bytes(4, "little"))
hash_bytes_prefixed(h_pr, address_resp.address.encode())
elif isinstance(memo, CoinPurchaseMemo):
address_resp = btc.get_authenticated_address(
client, memo.coin_name, memo.address_n
)
msg_memo = messages.CoinPurchaseMemo(
coin_type=memo.slip44,
amount=memo.amount,
address=address_resp.address,
mac=address_resp.mac,
)
msg_memos.append(messages.PaymentRequestMemo(coin_purchase_memo=msg_memo))
memo_type = 3
h_pr.update(memo_type.to_bytes(4, "little"))
h_pr.update(memo.slip44.to_bytes(4, "little"))
hash_bytes_prefixed(h_pr, memo.amount.encode())
hash_bytes_prefixed(h_pr, address_resp.address.encode())
else:
raise ValueError
h_pr.update(SLIP44.to_bytes(4, "little"))
change_address = iter(change_addresses or [])
h_outputs = sha256()
for txo in outputs:
h_outputs.update(txo.amount.to_bytes(8, "little"))
address = txo.address or next(change_address)
h_outputs.update(len(address).to_bytes(1, "little"))
h_outputs.update(address.encode())
h_pr.update(h_outputs.digest())
return messages.TxAckPaymentRequest(
recipient_name=recipient_name,
amount=sum(txo.amount for txo in outputs if txo.address),
memos=msg_memos,
nonce=nonce,
signature=payment_req_signer.sign_digest_deterministic(h_pr.digest()),
)
def make_coinjoin_request(
coordinator_name,
inputs,
input_script_pubkeys,
outputs,
output_script_pubkeys,
no_fee_indices,
fee_rate=500_000, # 0.5 %
no_fee_threshold=1_000_000,
min_registrable_amount=5_000,
):
# Reuse the signing key as the masking key to ensure deterministic behavior.
# Note that in production the masking key should be generated randomly.
ecdh = ECDH(curve=SECP256k1)
ecdh.load_private_key(payment_req_signer)
mask_public_key = ecdh.get_public_key().to_string("compressed")
# Process inputs.
h_prevouts = sha256()
coinjoin_flags = bytearray()
for i, (txi, script_pubkey) in enumerate(zip(inputs, input_script_pubkeys)):
# Add input to prevouts hash.
h_prevouts.update(bytes(reversed(txi.prev_hash)))
h_prevouts.update(txi.prev_index.to_bytes(4, "little"))
# Set signable flag in coinjoin_flags.
if len(script_pubkey) == 34 and script_pubkey.startswith(b"\x51\x20"):
ecdh.load_received_public_key_bytes(b"\x02" + script_pubkey[2:])
shared_secret = ecdh.generate_sharedsecret_bytes()
h_mask = sha256(shared_secret)
h_mask.update(bytes(reversed(txi.prev_hash)))
h_mask.update(txi.prev_index.to_bytes(4, "little"))
mask = h_mask.digest()[0] & 1
signable = bool(txi.address_n)
txi.coinjoin_flags = signable ^ mask
else:
txi.coinjoin_flags = 0
# Set no_fee flag in coinjoin_flags.
txi.coinjoin_flags |= (i in no_fee_indices) << 1
coinjoin_flags.append(txi.coinjoin_flags)
# Process outputs.
h_outputs = sha256()
for txo, script_pubkey in zip(outputs, output_script_pubkeys):
h_outputs.update(txo.amount.to_bytes(8, "little"))
hash_bytes_prefixed(h_outputs, script_pubkey)
# Hash the CoinJoin request.
h_request = sha256(b"CJR1")
hash_bytes_prefixed(h_request, coordinator_name.encode())
h_request.update(SLIP44.to_bytes(4, "little"))
h_request.update(fee_rate.to_bytes(4, "little"))
h_request.update(no_fee_threshold.to_bytes(8, "little"))
h_request.update(min_registrable_amount.to_bytes(8, "little"))
h_request.update(mask_public_key)
hash_bytes_prefixed(h_request, coinjoin_flags)
h_request.update(h_prevouts.digest())
h_request.update(h_outputs.digest())
return messages.CoinJoinRequest(
fee_rate=fee_rate,
no_fee_threshold=no_fee_threshold,
min_registrable_amount=min_registrable_amount,
mask_public_key=mask_public_key,
signature=payment_req_signer.sign_digest_deterministic(h_request.digest()),
)