def test_serialize_txgroup(self):
address = "7ZUECA7HFLZTXENRV24SHLU4AVPUTMTTDUFUBNBD64C73F3UHRTHAIOF6Q"
gh = "JgsgCaCTqIaLeVhyL6XlRu3n7Rfk2FxMeK+wRSaQ7dI="
txn = transaction.PaymentTxn(address,
3,
1,
100,
gh,
address,
1000,
gen="testnet-v1.0",
close_remainder_to=address)
txid = txn.get_txid().encode()
txid = base64.decodebytes(txid)
txgroup = transaction.TxGroup([txid])
enc = encoding.msgpack_encode(txgroup)
re_enc = encoding.msgpack_encode(encoding.msgpack_decode(enc))
self.assertEqual(enc, re_enc)
txgroup = transaction.TxGroup([txid] * 11)
enc = encoding.msgpack_encode(txgroup)
re_enc = encoding.msgpack_encode(encoding.msgpack_decode(enc))
self.assertEqual(enc, re_enc)
# check group field serialization
gid = transaction.calculate_group_id([txn, txn])
txn.group = gid
enc = encoding.msgpack_encode(txn)
re_enc = encoding.msgpack_encode(encoding.msgpack_decode(enc))
self.assertEqual(enc, re_enc)
def sendTransaction(privateKey_def, addr_def, addr_acl_1, addr_acl_2,
addr_acl_3, amount):
# Create two seperate transactions
trxn_1 = create_transaction(privateKey_def, addr_def, addr_acl_1, amount)
trxn_2 = create_transaction(privateKey_def, addr_def, addr_acl_2, amount)
trxn_3 = create_transaction(privateKey_def, addr_def, addr_acl_3, amount)
# Make transactions into group
gid = transaction.calculate_group_id([trxn_1, trxn_2, trxn_3])
trxn_1.group = gid
trxn_2.group = gid
trxn_3.group = gid
# sign the transaction
signTrxn_1 = trxn_1.sign(privateKey_def)
signTrxn_2 = trxn_2.sign(privateKey_def)
signTrxn_3 = trxn_3.sign(privateKey_def)
# trxn_id = signTrxn.transaction.get_txid()
try:
return ("Transactions were signed with: ",
algodClient.send_transactions(
[signTrxn_1, signTrxn_2, signTrxn_3],
headers={'content-type': 'application/x-binary'}))
except Exception as e:
print(e)
# gn="testnet-v1.0"
# genhash="SGO1GKSzyE7IEPItTxCByw9x8FmnrCDexi9/cOUJOiI="
def sc_opt_in(self,sc_addr,sc_lsig,asset_id):
txn = self.sc_opt_in_asset(sc_addr,asset_id)
gid = transaction.calculate_group_id([txn])
txn.group = gid
lstx = LogicSigTransaction(txn, sc_lsig)
signedGroup = []
signedGroup.append(lstx)
tx_id = self.algod_client.send_transactions(signedGroup)
self.wait_for_confirmation(tx_id)
def group_transactions() :
# recover a account
passphrase1 = <25-word-passphrase>
pk_account_a = mnemonic.to_private_key(passphrase1)
account_a = account.address_from_private_key(pk_account_a)
# recover b account
passphrase2 = <25-word-passphrase>
pk_account_b = mnemonic.to_private_key(passphrase2)
account_b = account.address_from_private_key(pk_account_b)
# recover c account
passphrase3 = <25-word-passphrase>
pk_account_c = mnemonic.to_private_key(passphrase3)
account_c = account.address_from_private_key(pk_account_c)
# connect to node
acl = connect_to_network()
# get suggested parameters
params = acl.suggested_params()
gen = params["genesisID"]
gh = params["genesishashb64"]
last_round = params["lastRound"]
fee = params["fee"]
amount = 1000
# create transaction1
txn1 = transaction.PaymentTxn(account_a, fee, last_round, last_round+100, gh, account_c, amount)
# create transaction2
txn2 = transaction.PaymentTxn(account_b, fee, last_round, last_round+100, gh, account_a, amount)
# get group id and assign it to transactions
gid = transaction.calculate_group_id([txn1, txn2])
txn1.group = gid
txn2.group = gid
# sign transaction1
stxn1 = txn1.sign(pk_account_a)
# sign transaction2
stxn2 = txn2.sign(pk_account_b)
signedGroup = []
signedGroup.append(stxn1)
signedGroup.append(stxn2)
# send them over network
sent = acl.send_transactions(signedGroup)
# print txid
print(sent)
# wait for confirmation
wait_for_confirmation( acl, sent)
def group_transactions():
# recover a account
passphrase1 = os.getenv("MNEMONIC1")
pk_account_a = mnemonic.to_private_key(passphrase1)
account_a = account.address_from_private_key(pk_account_a)
# recover b account
account_b = "4O6BRAPVLX5ID23AZWV33TICD35TI6JWOHXVLPGO4VRJATO6MZZQRKC7RI"
# connect to node
acl = connect_to_network()
# get suggested parameters
params = acl.suggested_params()
gen = params["genesisID"]
gh = params["genesishashb64"]
last_round = params["lastRound"]
fee = params["fee"]
asset_index = 14035004
# create transaction1
txn1 = transaction.PaymentTxn(account_a, fee, last_round, last_round + 100,
gh, account_b, 42000000)
# create transaction2
txn2 = transaction.AssetTransferTxn(account_b, fee, last_round,
last_round + 100, gh, account_a, 1,
asset_index)
# get group id and assign it to transactions
gid = transaction.calculate_group_id([txn1, txn2])
txn1.group = gid
txn2.group = gid
# sign transaction1
stxn1 = txn1.sign(pk_account_a)
# sign transaction2
with open("buildweb3/step5.lsig", "rb") as f:
lsig = encoding.future_msgpack_decode(base64.b64encode(f.read()))
stxn2 = transaction.LogicSigTransaction(txn2, lsig)
signedGroup = []
signedGroup.append(stxn1)
signedGroup.append(stxn2)
# send them over network
sent = acl.send_transactions(signedGroup)
# print txid
print(sent)
# wait for confirmation
wait_for_confirmation(acl, sent)
def test_transaction_group(self):
# get the default wallet
wallets = self.kcl.list_wallets()
wallet_id = None
for w in wallets:
if w["name"] == wallet_name:
wallet_id = w["id"]
# get a new handle for the wallet
handle = self.kcl.init_wallet_handle(wallet_id, wallet_pswd)
# get private key
private_key_0 = self.kcl.export_key(handle, wallet_pswd,
self.account_0)
# get suggested parameters and fee
params = self.acl.suggested_params()
gen = params["genesisID"]
gh = params["genesishashb64"]
last_round = params["lastRound"]
fee = params["fee"]
# create transaction
txn = transaction.PaymentTxn(self.account_0,
fee,
last_round,
last_round + 100,
gh,
self.account_0,
1000,
gen=gen)
# calculate group id
gid = transaction.calculate_group_id([txn])
txn.group = gid
# sign using kmd
stxn1 = self.kcl.sign_transaction(handle, wallet_pswd, txn)
# sign using transaction call
stxn2 = txn.sign(private_key_0)
# check that they are the same
self.assertEqual(encoding.msgpack_encode(stxn1),
encoding.msgpack_encode(stxn2))
try:
send = self.acl.send_transactions([stxn1])
self.assertEqual(send, txn.get_txid())
except error.AlgodHTTPError as ex:
self.assertIn(
"TransactionPool.Remember: transaction groups not supported",
str(ex))
def bet_atomic_transfer(algod_client, dealer, addr_opponent,
addr_dealer_bet_escrow, addr_opponent_bet_escrow,
microalgo_bet_amount):
"""HELP bet_atomic_transfer:
(AlgodClient, dict, str, str, str, int) - Returns Bet Atomic Transfer
partially signed by the Dealer, to be signed by the Opponent.
"""
dealer_bet_txn = unsigned_send(algod_client, dealer['pk'],
addr_dealer_bet_escrow,
microalgo_bet_amount)
opponent_bet_txn = unsigned_send(algod_client, addr_opponent,
addr_opponent_bet_escrow,
microalgo_bet_amount)
# Gorup Transaction
gid = transaction.calculate_group_id([dealer_bet_txn, opponent_bet_txn])
dealer_bet_txn.group = gid
opponent_bet_txn.group = gid
dealer_bet_stxn = dealer_bet_txn.sign(dealer['sk'])
return dealer_bet_stxn, opponent_bet_txn
def complete_trade(update, context):
"""
To complete the atomic transaction, Buyer signs and submit half-signed transaction.
:param update: Telegram obj.
:param context: Telegram obj.
:param context: Authorization key from the buyer.
:return:
"""
sk = context.user_data['Authorization_key']
_address = account.address_from_private_key(sk)
sk_bytes = rf(update, context, _address)
bt = base64.decodebytes(sk_bytes)
s = bt.decode()
key = _address[:10]
seller = TRANSACTIONS["{}".format(key)]['Seller']
update.message.reply_text("Completing trade...\nbetween:\nSeller - {} and Buyer - {}".format(seller, _address))
file = _address[:11]
if _address in ex_file and _address == TRANSACTIONS["{}".format(key)]['Buyer']:
rtv = transaction.retrieve_from_file("./asa{}.txn".format(file))
grid = transaction.calculate_group_id([rtv[0], rtv[1], rtv[2], rtv[3]])
rtv[0].group = grid
rtv[1].group = grid
rtv[2].group = grid
rtv[3].group = grid
txn1 = rtv[0].sign(sk)
txn2 = rtv[1].sign(sk)
txn3 = rtv[2].sign(s)
txn4 = rtv[3].sign(s)
tx_id = client.send_transactions([txn1, txn2, txn3, txn4])
wait_for_confirmation(update, context, client, tx_id)
else:
update.message.reply_text("Trade could not be completed!")
context.user_data.clear()
remove_data(update, context, _address)
return ConversationHandler.conversation_timeout
def play_last_turn(algod_client, player, addr_adversary, addr_game_table,
game_table_lsig, addr_sink, sink_lsig,
addr_adversary_bet_escrow, adversary_bet_escrow_lsig,
asa_turn_id, asa_pieces_id, asa_pieces_amount,
asa_pieces_total):
"""HELP play_last_turn:
(AlgodClient, dict, str, str, str, str, str, str, str, int, int, int,
int) - Play last turn moving ASA Pieces form the Game Table to the
Sink and show the winning proof to the opponent's Bet Escrow.
"""
txn0 = unsigned_asset_send(algod_client, player['pk'], addr_adversary,
asa_turn_id, 1)
txn1 = unsigned_asset_send(algod_client, addr_game_table, addr_sink,
asa_pieces_id, asa_pieces_amount)
txn2 = unsigned_asset_send(algod_client, addr_sink, player['pk'],
asa_pieces_id, asa_pieces_total)
txn3 = unsigned_closeto(algod_client, addr_adversary_bet_escrow,
player['pk'])
# Gorup Transaction
gid = transaction.calculate_group_id([txn0, txn1, txn2, txn3])
txn0.group = gid
txn1.group = gid
txn2.group = gid
txn3.group = gid
stxn0 = txn0.sign(player['sk'])
lstxn1 = transaction.LogicSigTransaction(txn1, game_table_lsig)
lstxn2 = transaction.LogicSigTransaction(txn2, sink_lsig)
lstxn3 = transaction.LogicSigTransaction(txn3, adversary_bet_escrow_lsig)
sgtxn = [stxn0, lstxn1, lstxn2, lstxn3]
txid = algod_client.send_transactions(sgtxn)
print("\nI WON !!! Arrivederci " + addr_adversary)
print("Transaction ID: ", txid)
wait_for_tx_confirmation(algod_client, txid)
def test_sign(self):
mn = ("advice pudding treat near rule blouse same whisper inner " +
"electric quit surface sunny dismiss leader blood seat " +
"clown cost exist hospital century reform able sponsor")
gh = "JgsgCaCTqIaLeVhyL6XlRu3n7Rfk2FxMeK+wRSaQ7dI="
address = "PNWOET7LLOWMBMLE4KOCELCX6X3D3Q4H2Q4QJASYIEOF7YIPPQBG3YQ5YI"
close = "IDUTJEUIEVSMXTU4LGTJWZ2UE2E6TIODUKU6UW3FU3UKIQQ77RLUBBBFLA"
sk = mnemonic.to_private_key(mn)
pk = account.address_from_private_key(sk)
txn = transaction.PaymentTxn(pk,
4,
12466,
13466,
gh,
address,
1000,
note=base64.b64decode("6gAVR0Nsv5Y="),
gen="devnet-v33.0",
close_remainder_to=close)
stx = txn.sign(sk)
golden = ("gqNzaWfEQPhUAZ3xkDDcc8FvOVo6UinzmKBCqs0woYSfodlmBMfQvGbeU" +
"x3Srxy3dyJDzv7rLm26BRv9FnL2/AuT7NYfiAWjdHhui6NhbXTNA+ilY2" +
"xvc2XEIEDpNJKIJWTLzpxZpptnVCaJ6aHDoqnqW2Wm6KRCH/xXo2ZlZc0" +
"EmKJmds0wsqNnZW6sZGV2bmV0LXYzMy4womdoxCAmCyAJoJOohot5WHIv" +
"peVG7eftF+TYXEx4r7BFJpDt0qJsds00mqRub3RlxAjqABVHQ2y/lqNyY" +
"3bEIHts4k/rW6zAsWTinCIsV/X2PcOH1DkEglhBHF/hD3wCo3NuZMQg5/" +
"D4TQaBHfnzHI2HixFV9GcdUaGFwgCQhmf0SVhwaKGkdHlwZaNwYXk=")
self.assertEqual(golden, encoding.msgpack_encode(stx))
txid_golden = "5FJDJD5LMZC3EHUYYJNH5I23U4X6H2KXABNDGPIL557ZMJ33GZHQ"
self.assertEqual(txn.get_txid(), txid_golden)
# check group field serialization
gid = transaction.calculate_group_id([txn])
stx.group = gid
enc = encoding.msgpack_encode(stx)
re_enc = encoding.msgpack_encode(encoding.msgpack_decode(enc))
self.assertEqual(enc, re_enc)
def play_turn(algod_client, player, addr_adversary, addr_game_table,
game_table_lsig, addr_sink, sink_lsig, addr_adversary_bet_escrow,
adversary_bet_escrow_lsig, asa_turn_id, asa_pieces_id,
asa_pieces_max_remove, asa_pieces_amount, asa_pieces_total):
"""HELP play_turn:
(AlgodClient, dict, str, str, str, str, str, str, str, int, int, int,
int) - Play turn moving ASA Pieces form the Game Table to the Sink.
"""
game_table_info = algod_client.account_info(addr_game_table)
pieces_on_table = next((asa['amount'] for asa in game_table_info['assets']
if asa['asset-id'] == asa_pieces_id), None)
if pieces_on_table > asa_pieces_max_remove:
txn0 = unsigned_asset_send(algod_client, player['pk'], addr_adversary,
asa_turn_id, 1)
txn1 = unsigned_asset_send(algod_client, addr_game_table, addr_sink,
asa_pieces_id, asa_pieces_amount)
# Gorup Transaction
gid = transaction.calculate_group_id([txn0, txn1])
txn0.group = gid
txn1.group = gid
stxn0 = txn0.sign(player['sk'])
lstxn1 = transaction.LogicSigTransaction(txn1, game_table_lsig)
sgtxn = [stxn0, lstxn1]
txid = algod_client.send_transactions(sgtxn)
print("\nRemoving", asa_pieces_amount, "pieces from the Game Table...")
print("Transaction ID: ", txid)
wait_for_tx_confirmation(algod_client, txid)
else:
play_last_turn(algod_client, player, addr_adversary, addr_game_table,
game_table_lsig, addr_sink, sink_lsig,
addr_adversary_bet_escrow, adversary_bet_escrow_lsig,
asa_turn_id, asa_pieces_id, asa_pieces_amount,
asa_pieces_total)
def match_setup(algod_client, dealer_passphrase, addr_opponent,
match_hours_timeout, microalgo_bet_amount, asa_pieces_total,
asa_pieces_max_remove):
"""HELP match_setup:
(AlgodClient, str, str, float, int, int, int) - Sets up a new AlgoNim
match.
"""
# AlgoNim Players
# Palyer 1 (Dealer) - Match Set Up costs about: 0.8 ALGO
dealer = {
'pk': mnemonic.to_public_key(dealer_passphrase),
'sk': mnemonic.to_private_key(dealer_passphrase)
}
# Player 2 (Opponent) - Must Opt-In AlgoNim ASAs to play the match
opponent = {'pk': addr_opponent}
print(" ")
print(" _ __ ____ _____ _ ")
print(" / \ [ | |_ \|_ _| (_) ")
print(" / _ \ | | .--./) .--. | \ | | __ _ .--..--. ")
print(" / ___ \ | | / /'`\;/ .'`\ \ | |\ \| | [ | [ `.-. .-. | ")
print(" _/ / \ \_ | | \ \._//| \__. |_| |_\ |_ | | | | | | | | ")
print("|____| |____|[___].',__` '.__.'|_____|\____|[___][___||__||__]")
print(" ( ( __)) ")
print(" by cusma")
print(" ")
print(" Welcome to AlgoNim, the first crypto-mini-game on Algorand! ")
# Asset Create: AlgoNim ASA Pieces
print("")
print("Dealer creating AlgoNim ASA Piece for this match...")
asa_pieces_id = asa_pieces_create(algod_client, dealer, asa_pieces_total)
# Asset Create: AlgoNim ASA Turn
print("")
print("Dealer creating AlgoNim ASA Turn for this match...")
asa_turn_id = asa_turn_create(algod_client, dealer)
# TEAL: AlgoNim ASC1 Sink
print("")
print("Dealer writing AlgoNim ASC1 Sink TEAL for this match...")
asc1_sink_source = asc1_sink_teal(asa_pieces_total, asa_pieces_id,
dealer['pk'], opponent['pk'])
asc1_sink_compiled = algod_client.compile(asc1_sink_source)
sink_lsig = transaction.LogicSig(
base64.decodebytes(asc1_sink_compiled['result'].encode()))
addr_sink = asc1_sink_compiled['hash']
# Initialize AlgoNim ASC1 Sink Account with ALGO
print("")
print("Initializing Sink Account...")
send(algod_client, dealer, addr_sink, 300000)
# AlgoNim ASC1 Sink Account Opt-In
print("")
print("Sink Account AlgoNim ASA Piece Opt-In...")
sink_opt_in_txn = unsigned_asset_send(algod_client, addr_sink, addr_sink,
asa_pieces_id, 0)
sink_opt_in_lstxn = transaction.LogicSigTransaction(
sink_opt_in_txn, sink_lsig)
txid = algod_client.send_transactions([sink_opt_in_lstxn])
print("Transaction ID:", txid)
wait_for_tx_confirmation(algod_client, txid)
# TEAL: AlgoNim ASC1 Game Table
print("")
print("Dealer writing AlgoNim ASC1 Game Table TEAL for this match...")
asc1_game_table_source = asc1_game_table_teal(asa_pieces_total,
asa_pieces_id,
asa_pieces_max_remove,
asa_turn_id, dealer['pk'],
opponent['pk'], addr_sink)
asc1_game_table_compiled = algod_client.compile(asc1_game_table_source)
game_table_lsig = transaction.LogicSig(
base64.decodebytes(asc1_game_table_compiled['result'].encode()))
addr_game_table = asc1_game_table_compiled['hash']
# Initialize AlgoNim ASC1 Game Table Account with ALGO
print("")
print("Initializing Game Table Account...")
send(algod_client, dealer, addr_game_table, 300000)
# Dealer Sets Up the Game Table with AlgoNim ASA Pieces
print("")
print("Dealer distributing ASA Pieces on the Game Table...")
gt_opt_in_txn = unsigned_asset_send(algod_client, addr_game_table,
addr_game_table, asa_pieces_id, 0)
deal_pieces_txn = unsigned_asset_send(algod_client, dealer['pk'],
addr_game_table, asa_pieces_id,
asa_pieces_total)
# Dealer Gorup Transaction
dealer_gid = transaction.calculate_group_id(
[gt_opt_in_txn, deal_pieces_txn])
gt_opt_in_txn.group = dealer_gid
deal_pieces_txn.group = dealer_gid
gt_opt_in_lstxn = transaction.LogicSigTransaction(gt_opt_in_txn,
game_table_lsig)
deal_pieces_stxn = deal_pieces_txn.sign(dealer['sk'])
dealer_sgtxn = [gt_opt_in_lstxn, deal_pieces_stxn]
txid = algod_client.send_transactions(dealer_sgtxn)
print("Transaction ID: ", txid)
wait_for_tx_confirmation(algod_client, txid)
# TEAL: AlgoNim ASC1 Bet Escrow
print("")
print("Dealer writing AlgoNim ASC1 Bet Escrow TEAL for Palyer 1...")
asc1_dealer_bet_escrow_source, dealer_bet_escrow_expiry_block = asc1_bet_escrow_teal(
algod_client, asa_pieces_total, asa_pieces_id, asa_turn_id,
dealer['pk'], opponent['pk'], addr_sink, addr_game_table,
match_hours_timeout)
asc1_dealer_bet_escrow_compiled = algod_client.compile(
asc1_dealer_bet_escrow_source)
dealer_bet_escrow_lsig = transaction.LogicSig(
base64.decodebytes(asc1_dealer_bet_escrow_compiled['result'].encode()))
addr_dealer_bet_escrow = asc1_dealer_bet_escrow_compiled['hash']
print("")
print("Dealer writing AlgoNim ASC1 Bet Escrow TEAL for Palyer 2...")
asc1_opponent_bet_escrow_source, opponent_bet_escrow_expiry_block = asc1_bet_escrow_teal(
algod_client, asa_pieces_total, asa_pieces_id, asa_turn_id,
opponent['pk'], dealer['pk'], addr_sink, addr_game_table,
match_hours_timeout)
asc1_opponent_bet_escrow_compiled = algod_client.compile(
asc1_opponent_bet_escrow_source)
opponent_bet_escrow_lsig = transaction.LogicSig(
base64.decodebytes(
asc1_opponent_bet_escrow_compiled['result'].encode()))
addr_opponent_bet_escrow = asc1_opponent_bet_escrow_compiled['hash']
# Initialize AlgoNim ASC1 Escrows with 0.1 ALGO
print("")
print("Initializing Bet Escrow Accounts...")
send(algod_client, dealer, addr_dealer_bet_escrow, 100000)
print("")
send(algod_client, dealer, addr_opponent_bet_escrow, 100000)
# Creating Bet Atomic Transfer to be signed by the Opponent
dealer_bet_stxn, opponent_bet_txn = bet_atomic_transfer(
algod_client, dealer, opponent['pk'], addr_dealer_bet_escrow,
addr_opponent_bet_escrow, microalgo_bet_amount)
match_data = {}
match_data['dealer'] = dealer['pk']
match_data['opponent'] = opponent['pk']
match_data['asa_pieces_id'] = asa_pieces_id
match_data['asa_pieces_max_remove'] = asa_pieces_max_remove
match_data['asa_turn_id'] = asa_turn_id
match_data['sink'] = addr_sink
match_data['sink_lsig'] = encoding.msgpack_encode(sink_lsig)
match_data['game_table'] = addr_game_table
match_data['game_table_lsig'] = encoding.msgpack_encode(game_table_lsig)
match_data['dealer_bet_escrow'] = addr_dealer_bet_escrow
match_data['dealer_bet_escrow_lsig'] = encoding.msgpack_encode(
dealer_bet_escrow_lsig)
match_data['opponent_bet_escrow'] = addr_opponent_bet_escrow
match_data['opponent_bet_escrow_lsig'] = encoding.msgpack_encode(
opponent_bet_escrow_lsig)
match_data['dealer_bet_stxn'] = encoding.msgpack_encode(dealer_bet_stxn)
match_data['opponent_bet_txn'] = encoding.msgpack_encode(opponent_bet_txn)
match_data['microalgo_bet_amount'] = microalgo_bet_amount
match_data['match_hours_timeout'] = match_hours_timeout
match_data['dealer_bet_escrow_expiry'] = dealer_bet_escrow_expiry_block
match_data['opponent_bet_escrow_expiry'] = opponent_bet_escrow_expiry_block
match_data_bytes = msgpack.packb(match_data)
match_data_fname = 'algonim.match'
with open(match_data_fname, "wb") as f:
f.write(match_data_bytes)
f.close()
print(" ")
print(" _ _ ")
print(" /\/\ __ _| |_ ___| |__ _ ")
print(" / \ / _` | __/ __| '_ \ (_)")
print("/ /\/\ \ (_| | || (__| | | | _ ")
print("\/ \/\__,_|\__\___|_| |_| (_)")
print(" ")
print("MATCH DURATION:\t\t", match_data['match_hours_timeout'] * 60, "min")
print("PIECES ON GAME TABLE:\t", asa_pieces_total, "\n")
print("RULES:")
print("1. Players on each turn must remove at least 1 ASA Piece")
print("2. Players on each turn must remove at most",
match_data['asa_pieces_max_remove'], "ASA Piece")
print("3. Who removes the last ASA Piece form the Game Table wins the " +
"match!\n")
print("Player 1 - Dealer:\t" + match_data['dealer'])
print("Player 2 - Opponent:\t" + match_data['opponent'], "\n")
print("AlgoNim ASA Pieces ID:\t", match_data['asa_pieces_id'])
print("AlgoNim ASA Turn ID:\t", match_data['asa_turn_id'], "\n")
print("AlgoNim Sink Account:\t\t\t" + match_data['sink'])
print("AlgoNim Game Table Account:\t\t" + match_data['game_table'])
print("AlgoNim Bet Escrow Player 1 Account:\t" +
match_data['dealer_bet_escrow'])
print("AlgoNim Bet Escrow Player 2 Account:\t" +
match_data['opponent_bet_escrow'])
print("\nSend 'algonim.match' file to your opponent join the match!\n")
print("May the best win!\n")
def test_group_id(self):
address = "UPYAFLHSIPMJOHVXU2MPLQ46GXJKSDCEMZ6RLCQ7GWB5PRDKJUWKKXECXI"
fromAddress, toAddress = address, address
fee = 1000
amount = 2000
genesisID = "devnet-v1.0"
genesisHash = "sC3P7e2SdbqKJK0tbiCdK9tdSpbe6XeCGKdoNzmlj0E="
firstRound1 = 710399
note1 = base64.b64decode("wRKw5cJ0CMo=")
tx1 = transaction.PaymentTxn(fromAddress,
fee,
firstRound1,
firstRound1 + 1000,
genesisHash,
toAddress,
amount,
note=note1,
gen=genesisID,
flat_fee=True)
firstRound2 = 710515
note2 = base64.b64decode("dBlHI6BdrIg=")
tx2 = transaction.PaymentTxn(fromAddress,
fee,
firstRound2,
firstRound2 + 1000,
genesisHash,
toAddress,
amount,
note=note2,
gen=genesisID,
flat_fee=True)
# goal clerk send dumps unsigned transaction as signed with empty signature in order to save tx type
stx1 = transaction.SignedTransaction(tx1, None)
stx2 = transaction.SignedTransaction(tx2, None)
goldenTx1 = (
"gaN0eG6Ko2FtdM0H0KNmZWXNA+iiZnbOAArW/6NnZW6rZGV2bmV0LXYxLjCiZ2j" +
"EILAtz+3tknW6iiStLW4gnSvbXUqW3ul3ghinaDc5pY9Bomx2zgAK2uekbm90Zc" +
"QIwRKw5cJ0CMqjcmN2xCCj8AKs8kPYlx63ppj1w5410qkMRGZ9FYofNYPXxGpNL" +
"KNzbmTEIKPwAqzyQ9iXHremmPXDnjXSqQxEZn0Vih81g9fEak0spHR5cGWjcGF5")
goldenTx2 = (
"gaN0eG6Ko2FtdM0H0KNmZWXNA+iiZnbOAArXc6NnZW6rZGV2bmV0LXYxLjCiZ2j" +
"EILAtz+3tknW6iiStLW4gnSvbXUqW3ul3ghinaDc5pY9Bomx2zgAK21ukbm90Zc" +
"QIdBlHI6BdrIijcmN2xCCj8AKs8kPYlx63ppj1w5410qkMRGZ9FYofNYPXxGpNL"
"KNzbmTEIKPwAqzyQ9iXHremmPXDnjXSqQxEZn0Vih81g9fEak0spHR5cGWjcGF5")
self.assertEqual(goldenTx1, encoding.msgpack_encode(stx1))
self.assertEqual(goldenTx2, encoding.msgpack_encode(stx2))
# preserve original tx{1,2} objects
tx1 = copy.deepcopy(tx1)
tx2 = copy.deepcopy(tx2)
gid = transaction.calculate_group_id([tx1, tx2])
stx1.transaction.group = gid
stx2.transaction.group = gid
# goal clerk group sets Group to every transaction and concatenate them in output file
# simulating that behavior here
txg = base64.b64encode(
base64.b64decode(encoding.msgpack_encode(stx1)) +
base64.b64decode(encoding.msgpack_encode(stx2))).decode()
goldenTxg = (
"gaN0eG6Lo2FtdM0H0KNmZWXNA+iiZnbOAArW/6NnZW6rZGV2bmV0LXYxLjCiZ2j" +
"EILAtz+3tknW6iiStLW4gnSvbXUqW3ul3ghinaDc5pY9Bo2dycMQgLiQ9OBup9H" +
"/bZLSfQUH2S6iHUM6FQ3PLuv9FNKyt09SibHbOAAra56Rub3RlxAjBErDlwnQIy" +
"qNyY3bEIKPwAqzyQ9iXHremmPXDnjXSqQxEZn0Vih81g9fEak0so3NuZMQgo/AC" +
"rPJD2Jcet6aY9cOeNdKpDERmfRWKHzWD18RqTSykdHlwZaNwYXmBo3R4boujYW1" +
"0zQfQo2ZlZc0D6KJmds4ACtdzo2dlbqtkZXZuZXQtdjEuMKJnaMQgsC3P7e2Sdb" +
"qKJK0tbiCdK9tdSpbe6XeCGKdoNzmlj0GjZ3JwxCAuJD04G6n0f9tktJ9BQfZLq" +
"IdQzoVDc8u6/0U0rK3T1KJsds4ACttbpG5vdGXECHQZRyOgXayIo3JjdsQgo/AC" +
"rPJD2Jcet6aY9cOeNdKpDERmfRWKHzWD18RqTSyjc25kxCCj8AKs8kPYlx63ppj" +
"1w5410qkMRGZ9FYofNYPXxGpNLKR0eXBlo3BheQ==")
self.assertEqual(goldenTxg, txg)
# repeat test above for assign_group_id
txa1 = copy.deepcopy(tx1)
txa2 = copy.deepcopy(tx2)
txns = transaction.assign_group_id([txa1, txa2])
self.assertEqual(len(txns), 2)
stx1 = transaction.SignedTransaction(txns[0], None)
stx2 = transaction.SignedTransaction(txns[1], None)
# goal clerk group sets Group to every transaction and concatenate them in output file
# simulating that behavior here
txg = base64.b64encode(
base64.b64decode(encoding.msgpack_encode(stx1)) +
base64.b64decode(encoding.msgpack_encode(stx2))).decode()
self.assertEqual(goldenTxg, txg)
# check filtering
txns = transaction.assign_group_id([tx1, tx2], address=fromAddress)
self.assertEqual(len(txns), 2)
self.assertEqual(stx1.transaction.group, txns[0].group)
txns = transaction.assign_group_id([tx1, tx2], address="NONEXISTENT")
self.assertEqual(len(txns), 0)
