def test_002_insufficient_funds(self):
from electroncash_plugins.shuffle.coin import Coin
coin = Coin(self.network)
protocolThreads = self.make_clients_threads(with_print = True)
coins_1 = coin.get_coins(protocolThreads[0].inputs)
for pubkey in coins_1:
bad_addr = public_key_to_p2pkh(bytes.fromhex(pubkey))
for coin in coins_1[pubkey]:
coin['value'] = 0
self.network.coins[bad_addr] = coins_1[pubkey]
self.start_protocols(protocolThreads)
done = False
while not done:
completes = [self.is_protocol_complete(p) for p in protocolThreads[1:]]
done = all(completes)
self.stop_protocols(protocolThreads)
tx = protocolThreads[1].protocol.tx.raw
for pThread in protocolThreads[2:]:
self.assertEqual(tx, pThread.protocol.tx.raw)
print(protocolThreads[-1].protocol.tx.raw)
print(protocolThreads[-1].protocol.change_addresses)
class TestCoin(unittest.TestCase):
def __init__(self, *args, **kwargs):
super(TestCoin, self).__init__(*args, **kwargs)
self.network = testNetwork()
self.ec_keys = [random_sk() for _ in range(10)]
self.public_keys = [make_fake_public_key(secret_key=sk) for sk in self.ec_keys]
self.addresses = [address_from_public_key(public_key) for public_key in self.public_keys]
for address in self.addresses:
for value in [10000, 1000, 500, 100]:
self.network.add_coin(address, value, tx_hash = fake_hash(address, value))
self.coin = Coin(self.network)
def test_001_sufficient_funds(self):
pubkey_1, pubkey_2, pubkey_3 = self.public_keys[0:3]
address_1, address_2, address_3 = self.addresses[0:3]
address_x = "111111111111111111111111111"
inputs = {
pubkey_1:[
fake_hash(address_1, 1000) + ":0",
fake_hash(address_1, 100) + ":0"
],
pubkey_2:[
fake_hash(address_2, 1000) + ":0"]
}
self.assertTrue(self.coin.check_inputs_for_sufficient_funds(inputs, 2022))
self.assertFalse(self.coin.check_inputs_for_sufficient_funds(inputs, 20022))
bad_hash_input = {Hash("pubkey_1").hex():["a1h4"]}
self.assertIsNone(self.coin.check_inputs_for_sufficient_funds(bad_hash_input, 2222))
bad_address_input = {Hash("pubkey_111").hex():["a111h1"]}
self.assertIsNone(self.coin.check_inputs_for_sufficient_funds(bad_address_input, 2222))
def test_002_get_coins(self):
pubkey_1, pubkey_2, pubkey_3 = self.public_keys[0:3]
address_1, address_2, address_3 = self.addresses[0:3]
inputs = {
pubkey_1:[
fake_hash(address_1, 1000)+":0",
fake_hash(address_1, 100)+":0"
],
pubkey_2:[fake_hash(address_2, 1000)+":0"]
}
coins = self.coin.get_coins(inputs)
self.assertEquals(coins[pubkey_1][0]["value"], 1000)
self.assertEquals(coins[pubkey_1][0]["tx_hash"], fake_hash(address_1, 1000))
self.assertEquals(coins[pubkey_1][1]["value"], 100)
self.assertEquals(coins[pubkey_1][1]["tx_hash"], fake_hash(address_1, 100))
self.assertEquals(coins[pubkey_2][0]["value"], 1000)
self.assertEquals(coins[pubkey_2][0]["tx_hash"], fake_hash(address_2, 1000))
bad_input = {
pubkey_1:[fake_hash(address_2, 2222)]
}
coins = self.coin.get_coins(bad_input)
self.assertIsNone(coins)
def test_003_make_unsigned_transaction(self):
fee = 50
amount = 1000
pubkey_1, pubkey_2, pubkey_3, pubkey_4 = self.public_keys[0:4]
address_1, address_2, address_3, address_4 = self.addresses[0:4]
inputs = {
"player_1_vk":
{
pubkey_1:[
fake_hash(address_1, 500) + ":0",
fake_hash(address_1, 100) + ":0",
],
pubkey_2:[
fake_hash(address_2, 500) + ":0",
]
},
"player_2_vk":
{
pubkey_3:[
fake_hash(address_3, 1000) + ":0" ,
fake_hash(address_3, 100) + ":0",
]
},
"player_3_vk":
{
pubkey_4:[
fake_hash(address_4, 10000)+ ":0",
]
}
}
outputs = [make_fake_address() for _ in range(3)]
changes = { player:make_fake_address() for player in ["player_1_vk", "player_2_vk", "player_3_vk"]}
transaction = self.coin.make_unsigned_transaction(amount, fee, inputs, outputs, changes)
flat_inputs = [
{"public_key": pubkey_1, "address": address_1, "tx_hash": inputs["player_1_vk"][pubkey_1][0].split(":")[0], "value": 500},
{"public_key": pubkey_1, "address": address_1, "tx_hash": inputs["player_1_vk"][pubkey_1][1].split(":")[0], "value": 100},
{"public_key": pubkey_2, "address": address_2, "tx_hash": inputs["player_1_vk"][pubkey_2][0].split(":")[0], "value": 500},
{"public_key": pubkey_3, "address": address_3, "tx_hash": inputs["player_2_vk"][pubkey_3][0].split(":")[0], "value": 1000},
{"public_key": pubkey_3, "address": address_3, "tx_hash": inputs["player_2_vk"][pubkey_3][1].split(":")[0], "value": 100},
{"public_key": pubkey_4, "address": address_4, "tx_hash": inputs["player_3_vk"][pubkey_4][0].split(":")[0], "value": 10000},
]
flat_inputs.sort(key=lambda x:x["tx_hash"])
for i, input in enumerate(transaction.inputs()):
self.assertEquals(input['value'], flat_inputs[i]['value'])
self.assertEquals(input['tx_hash'], flat_inputs[i]['tx_hash'])
self.assertEquals(input['pubkeys'][0], flat_inputs[i]['public_key'])
self.assertEquals(input['address'].to_string(Address.FMT_LEGACY), flat_inputs[i]['address'])
amounts = {"player_1_vk":1100, "player_2_vk":1100, "player_3_vk":10000 }
flat_changes = [(changes[player], amounts[player]) for player in sorted(changes)]
flat_outputs = [
(0, Address.from_string(outputs[0]), amount),
(0, Address.from_string(outputs[1]), amount),
(0, Address.from_string(outputs[2]), amount),
(0, Address.from_string(flat_changes[0][0]), flat_changes[0][1] - amount -fee),
(0, Address.from_string(flat_changes[1][0]), flat_changes[1][1] - amount -fee),
(0, Address.from_string(flat_changes[2][0]), flat_changes[2][1] - amount - fee)
]
self.assertEquals(transaction.outputs(), flat_outputs)
def test_004_all_about_signatures(self):
fee = 50
amount = 1000
sk_1, sk_2, sk_3, sk_4 = self.ec_keys[0:4]
pubkey_1, pubkey_2, pubkey_3, pubkey_4 = self.public_keys[0:4]
address_1, address_2, address_3, address_4 = self.addresses[0:4]
inputs_vk_1 = {
pubkey_1:[
fake_hash(address_1, 500)+":0",
fake_hash(address_1, 100)+":0",
],
pubkey_2:[
fake_hash(address_2, 500)+":0",
]
}
inputs_vk_2 = {
pubkey_3:[
fake_hash(address_3, 1000)+":0",
fake_hash(address_3, 100)+":0",
]
}
inputs_vk_3 = {
pubkey_4:[
fake_hash(address_4, 10000)+":0",
]
}
inputs = {
"player_1_vk": inputs_vk_1,
"player_2_vk": inputs_vk_2,
"player_3_vk": inputs_vk_3
}
outputs = [make_fake_address() for _ in range(3)]
changes = { player:make_fake_address() for player in ["player_1_vk", "player_2_vk", "player_3_vk"]}
transaction = self.coin.make_unsigned_transaction(amount, fee, inputs, outputs, changes)
secret_keys_vk_1 = {pubkey_1:sk_1, pubkey_2: sk_2}
secret_keys_vk_2 = {pubkey_3:sk_3}
secret_keys_vk_3 = {pubkey_4:sk_4}
signatures = {}
signatures.update(self.coin.get_transaction_signature(transaction, inputs_vk_1, secret_keys_vk_1))
signatures.update(self.coin.get_transaction_signature(transaction, inputs_vk_2, secret_keys_vk_2))
signatures.update(self.coin.get_transaction_signature(transaction, inputs_vk_3, secret_keys_vk_3))
for player in inputs:
for pubkey in inputs[player]:
for tx_hash in inputs[player][pubkey]:
signature = signatures[tx_hash]
self.assertTrue(self.coin.verify_tx_signature(signature , transaction, pubkey, tx_hash))
self.coin.add_transaction_signatures(transaction, signatures)
def test_005_verigy_signatures(self):
message = b"some_message_for_test"
sk_1 = random_sk()
pubkey_1 = sk_1.get_public_key(True)
signature_1 = sk_1.sign_message(message, True)
self.assertTrue(self.coin.verify_signature(signature_1, message, pubkey_1))
sk_2 = random_sk()
pubkey_2 = sk_2.get_public_key(False)
signature_2 = sk_2.sign_message(message, False)
self.assertTrue(self.coin.verify_signature(signature_2, message, pubkey_2))
self.assertFalse(self.coin.verify_signature(signature_2, message, pubkey_1))
