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trezor-firmware/tests/device_tests/bitcoin/payment_req.py

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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()),
)