def create():
# Cryptographic Identities Generation
alice, bob = generate_keypair(), generate_keypair()
# Digital Asset Definition (e.g. bicycle)
asset = Asset(data={
"bicycle": {
"manufacturer": "bkfab",
"serial_number": "abcd1234"
}
})
# Metadata Definition
metadata = {'planet': 'earth'}
# create trnsaction TODO : owners_before might be node_pubkey in v0.8.0
tx = Transaction.create([alice.public_key], [([alice.public_key], 1)],
metadata=metadata,
asset=asset)
# sign with private key
tx = tx.sign([alice.private_key])
tx_id = tx.to_dict()['id']
# write to backlog
b = Bigchain()
b.write_transaction(tx)
# wait 2 sec
sleep(2)
# get tx by id
tx = b.get_transaction(tx_id)
return tx.to_dict()
def create_duplicate_tx():
##################################################### 1.CREATE
# Cryptographic Identities Generation
alice, bob = generate_keypair(), generate_keypair()
# Digital Asset Definition (e.g. bicycle)
asset = Asset(data={"bicycle": {"manufacturer": "bkfab", "serial_number": "abcd1234"}})
# Metadata Definition
metadata = {'planet': 'earth1'}
# create trnsaction TODO : owners_before might be node_pubkey in v0.8.0
tx = Transaction.create([alice.public_key], [([alice.public_key], 1)], metadata=metadata, asset=asset)
print(" ")
print("1.tx_create asset id : alice-----bicycle(", tx.to_dict()['transaction']['asset']['id'], ")----->alice")
print("1.tx_create tx id : ", tx.to_dict()['id'])
# sign with alice's private key
tx = tx.sign([alice.private_key])
tx_id = tx.to_dict()['id']
# write to backlog
b = Bigchain()
print("1.tx_create db response : ", b.write_transaction(tx))
# wait 2 sec
sleep(delay)
# get tx by id
tx = b.get_transaction(tx_id)
print("1.tx_create query : ", tx)
print(" ")
#####################################################
print("2.write dulpicate tx: ", b.write_transaction(tx))
def get():
# Cryptographic Identities Generation
alice, bob = generate_keypair(), generate_keypair()
print(" ")
# Digital Asset Definition (e.g. bicycle)
asset = Asset(data={
"bicycle": {
"manufacturer": "bkfab",
"serial_number": "abcd1234"
}
})
# Metadata Definition
metadata = {'planet': 'earth'}
# create trnsaction TODO : owners_before might be node_pubkey in v0.8.0
tx = Transaction.create([alice.public_key], [alice.public_key],
metadata=metadata,
asset=asset)
# sign with private key
tx = tx.sign([alice.private_key])
# get tx by id
b = Bigchain()
block = b.create_block([tx])
block_voters = block.to_dict()['block']['voters']
print(block_voters)
tx_id = '2cb004cad29c0b79872646558f8c867a4c0aecbc4997f0917'
tx = b.get_transaction(tx_id)
print(
"block status : ",
b.block_election_status(
'2257384a0cee8cf98bd82c3142dd38eee5c268c124b5b357b773b8c6c1fa1221',
block_voters))
def _generate_public_and_private_key_if_not_exist():
prifile = settings.PRIKEY_FILENAME
pubfile = settings.PUBKEY_FILENAME
if not (os.path.exists(prifile) and os.path.exists(pubfile)):
print('begin generate public and private key pair.')
generate_keypair()
print("generated public key file '%s' and private key file '%s'." %
(pubfile, prifile))
def bft():
# Cryptographic Identities Generation
alice, bob = generate_keypair(), generate_keypair()
print(" ")
# Digital Asset Definition (e.g. bicycle)
asset = Asset(data={
"bicycle": {
"manufacturer": "bkfab",
"serial_number": "abcd1234"
}
})
# Metadata Definition
metadata = {'planet': 'earth'}
# create trnsaction TODO : owners_before might be node_pubkey in v0.8.0
tx = Transaction.create([alice.public_key], [([alice.public_key], 1)],
metadata=metadata,
asset=asset)
# sign with private key
tx = tx.sign([alice.private_key])
tx_id = tx.to_dict()['id']
print("tx_id : ", tx_id)
# create block
b = Bigchain()
block = b.create_block([tx])
print("valid block timestamp : ",
block.to_dict()['block']['timestamp'])
# tamper block
block.timestamp = '1'
print("tamper block.timestamp to 1 : ")
block_id = block.to_dict()['id']
block_voters = block.to_dict()['block']['voters']
print("invalid block timestamp : ",
block.to_dict()['block']['timestamp'])
print("tamper_block_id : ", block_id)
print("db response of block : ", b.write_block(block))
sleep(0)
last_voted_id = b.get_last_voted_block().id
vote = b.vote(block_id, last_voted_id, True)
print("crate vote 'True' : ", vote)
print("db response of vote : ", b.write_vote(vote))
print("tamper_block status : ",
b.block_election_status(block_id, block_voters))
print("blocks_status_containing_tx : ",
b.get_blocks_status_containing_tx(tx_id))
print("wait for 20 sec : ")
sleep(20)
print("blocks_status_containing_tx : ",
b.get_blocks_status_containing_tx(tx_id))
print(" ")
def listen():
own_priv, own_pub = crypto.generate_keypair()
remote_sockets = []
remote_keys = []
def forever(s):
# Handshake.
while True:
data = s.recv(1024)
if data:
remote_user = name.User.from_bytes(data)
remote_sockets.append(s)
remote_keys.append(remote_user.pub)
ip = sock.Server(0, '').ip
us = name.User('a chat server', own_pub, ip, 'wellcome')
s.sendall(us.to_bytes())
break
# Accept text messages.
while True:
data = s.recv(1024)
if data:
assert(len(data) < 1024)
packet = pack.Packet.from_bytes(data)
text = crypto.decrypt(packet.encrypted, own_priv)
crypto.verify(text, packet.signature, remote_user.pub)
print(text)
time.sleep(0.1)
handle_input(remote_sockets, own_priv, remote_keys)
server = sock.Server(port.CHATSERVER, forever)
time.sleep(10)
server.alive = False
def tamper_block():
# Cryptographic Identities Generation
alice, bob = generate_keypair(), generate_keypair()
print(" ")
# Digital Asset Definition (e.g. bicycle)
asset = Asset(data={
"bicycle": {
"manufacturer": "bkfab",
"serial_number": "abcd1234"
}
})
# Metadata Definition
metadata = {'planet': 'earth'}
# create trnsaction TODO : owners_before might be node_pubkey in v0.8.0
tx = Transaction.create([alice.public_key], [([alice.public_key], 1)],
metadata=metadata,
asset=asset)
# sign with private key
tx = tx.sign([alice.private_key])
tx_id = tx.to_dict()['id']
print("tx_id : ", tx_id)
# create block
b = Bigchain()
block = b.create_block([tx])
block_id = block.to_dict()['id']
block_voters = block.to_dict()['block']['voters']
print("last_block_id sig : ", block_id, block.signature)
print(block.to_dict())
# tamper block sig
block.sign(alice.private_key)
block_dict = block.to_dict()
print("tamper_block_id sig : ", block_dict['id'],
block_dict['signature'])
print(block_dict)
print("db response : ",
b.backend.write_block(serialize(block_dict)))
sleep(delay)
print("tamper_block status : ",
b.block_election_status(block_dict['id'], block_voters))
print("blocks_status_containing_tx : ",
b.get_blocks_status_containing_tx(tx_id))
print(" ")
def test():
sock.test()
crypto.test()
pack.test()
time.sleep(2)
print('UNIT TESTS PASSED')
print()
Thread(target=listen).start()
time.sleep(1)
priv, pub = crypto.generate_keypair()
Thread(target=connect, args=['localhost', priv, pub]).start()
time.sleep(2)
print('INTEGRATION TEST PASSED')
print()
sys.exit()
def create_transfer():
##################################################### 1.CREATE
# Cryptographic Identities Generation
alice, bob = generate_keypair(), generate_keypair()
# Digital Asset Definition (e.g. bicycle)
asset = Asset(data={"bicycle": {"manufacturer": "bkfab", "serial_number": "abcd1234"}})
# Metadata Definition
metadata = {'planet': 'earth'}
# create trnsaction TODO : owners_before might be node_pubkey in v0.8.0
tx = Transaction.create([alice.public_key], [([alice.public_key], 1)], metadata=metadata, asset=asset)
print(" ")
print("1.tx_create asset id : alice-----bicycle(", tx.to_dict()['transaction']['asset']['id'], ")----->alice")
print("1.tx_create tx id : ", tx.to_dict()['id'])
# sign with alice's private key
tx = tx.sign([alice.private_key])
tx_id = tx.to_dict()['id']
# write to backlog
b = Bigchain()
print("1.tx_create db response : ", b.write_transaction(tx))
# wait 2 sec
sleep(delay)
# get tx by id
tx = b.get_transaction(tx_id)
print("1.tx_create query : ", tx)
# print("tx1_id:"+tx.to_dict()['id'])
print(" ")
##################################################### 2.TRANSFER
# inputs and asset [fake]
cid = 0
condition = tx.to_dict()['transaction']['conditions'][cid]
inputs = Fulfillment.from_dict({
'fulfillment': condition['condition']['details'],
'input': {
'cid': cid,
'txid': tx.to_dict()['id'],
},
'owners_before': [bob.public_key],
})
asset = Asset.from_dict(tx.to_dict()['transaction']['asset'])
# transfer
tx = Transaction.transfer([inputs], [([bob.public_key], 1)], asset)
print("2.tx_fake asset id : bob-----bicycle(", tx.to_dict()['transaction']['asset']['id'], ")----->bob")
print("2.tx_fake tx id : ", tx.to_dict()['id'])
# sign with bob's private key [fake]
tx = tx.sign([bob.private_key])
tx_id = tx.to_dict()['id']
# write to backlog
b = Bigchain()
print("2.tx_fake db response : ", b.write_transaction(tx))
# wait 2 sec
sleep(delay)
# get tx by id
tx = b.get_transaction(tx_id)
print("2.tx_fake query : ", tx)
# print("tx2_id:"+tx.to_dict()['id'])
print(" ")
def create_transfer():
##################################################### 1.CREATE
# Cryptographic Identities Generation
alice, bob, tom = generate_keypair(), generate_keypair(), generate_keypair(
)
asset = Asset(data={'money': 'RMB'},
data_id='20170628150000',
divisible=True)
metadata = {'planet': 'earth'}
tx = Transaction.create([alice.public_key], [([alice.public_key], 1000)],
metadata=metadata,
asset=asset)
print(" ")
print("1.tx_create asset id : alice-----money 1000(",
tx.to_dict()['transaction']['asset']['id'], ")----->alice")
print("1.tx_create tx id : ", tx.to_dict()['id'])
# sign with alice's private key
tx = tx.sign([alice.private_key])
tx_id = tx.to_dict()['id']
# write to backlog
b = Bigchain()
print("1.tx_create db response : ", b.write_transaction(tx))
# wait 4 sec
sleep(delay)
# get tx by id
tx = b.get_transaction(tx_id)
print("1.tx_create query : ", tx)
# print("tx1_id:"+tx.to_dict()['id'])
print(" ")
##################################################### 2.TRANSFER
# inputs and asset
cid = 0
condition = tx.to_dict()['transaction']['conditions'][cid]
inputs = Fulfillment.from_dict({
'fulfillment':
condition['condition']['details'],
'input': {
'cid': cid,
'txid': tx.to_dict()['id'],
},
'owners_before':
condition['owners_after'],
})
asset = Asset.from_dict(tx.to_dict()['transaction']['asset'])
# transfer
tx = Transaction.transfer([inputs], [([bob.public_key], 300),
([alice.public_key], 700)], asset)
print("2.tx_transfer asset id : alice-----money 300(",
tx.to_dict()['transaction']['asset']['id'], ")----->bob")
print("2.tx_transfer tx id : ", tx.to_dict()['id'])
print("2.tx_transfer tx : ", tx.to_dict())
print(" ")
# sign with alice's private key
tx = tx.sign([alice.private_key])
# man in the middle attack, then write to backlog
tx.conditions[0].amount = 600
tx.conditions[1].amount = 400
print("3.tx_attack asset id : alice-----money 600(",
tx.to_dict()['transaction']['asset']['id'], ")----->tom")
print("3.tx_attack tx id : ", tx.to_dict()['id'])
print("3.tx_attack tx : ", tx.to_dict())
tx_id = tx.to_dict()['id']
b = Bigchain()
print("3.tx_attack db response : ", b.write_transaction(tx))
# wait 4 sec
sleep(delay)
# get tx by id
tx = b.get_transaction(tx_id)
print("3.tx_attack query : ", tx)
print(" ")
def create_double():
##################################################### 1.CREATE
# Cryptographic Identities Generation
alice, bob = generate_keypair(), generate_keypair()
# Digital Asset Definition (e.g. money)
asset = Asset(data={'money': 'RMB'},
data_id='20170628150000',
divisible=True)
# Metadata Definition
metadata = {'planet': 'earth'}
# create trnsaction TODO : owners_before might be node_pubkey in v0.8.0
tx = Transaction.create([alice.public_key], [([alice.public_key], 100),
([alice.public_key], 100)],
metadata=metadata,
asset=asset)
print(" ")
print("1.tx_create asset id : alice-----money(",
tx.to_dict()['transaction']['asset']['id'], ")----->alice")
print("1.tx_create tx id : ", tx.to_dict()['id'])
# sign with alice's private key
tx = tx.sign([alice.private_key])
tx_id = tx.to_dict()['id']
# write to backlog
b = Bigchain()
print("1.tx_create db response : ", b.write_transaction(tx))
# wait 2 sec
sleep(delay)
# get tx by id
tx = b.get_transaction(tx_id)
unspent = b.get_outputs_filtered_not_include_freeze(
alice.public_key, False)
print("1.tx_create query : ", tx)
print("1.tx_create unspent : ", unspent)
print(" ")
##################################################### 2.TRANSFER
# inputs and asset
cid = 0
condition = tx.to_dict()['transaction']['conditions'][cid]
inputs = Fulfillment.from_dict({
'fulfillment':
condition['condition']['details'],
'input': {
'cid': cid,
'txid': tx.to_dict()['id'],
},
'owners_before': [alice.public_key],
})
asset = Asset.from_dict(tx.to_dict()['transaction']['asset'])
# transfer
tx1 = Transaction.transfer([inputs], [([bob.public_key], 100)], asset)
print("2.tx_transfer asset id : alice-----money(",
tx1.to_dict()['transaction']['asset']['id'], ")----->bob")
print("2.tx_transfer tx id : ", tx1.to_dict()['id'])
# sign with alice's private key
tx1 = tx1.sign([alice.private_key])
tx1_id = tx1.to_dict()['id']
# write to backlog
b = Bigchain()
print("2.tx_transfer db response : ", b.write_transaction(tx1))
# wait 2 sec
sleep(delay)
# get tx by id
tx1 = b.get_transaction(tx1_id)
block = list(b.get_blocks_status_containing_tx(tx1_id).keys())[0]
votes = list(b.backend.get_votes_by_block_id(block))
votes_cast = [vote['vote']['is_block_valid'] for vote in votes]
election = b.get_blocks_status_containing_tx(tx1_id)
print("2.tx_transfer query : ", tx1)
print("2.tx_transfer block : ", block)
print("2. votes : ", votes)
print("2. votes_cast : ", votes_cast)
print("2. election : ", election)
print(" ")
##################################################### 3.INTERVAL
# Cryptographic Identities Generation
alice, bob = generate_keypair(), generate_keypair()
# Digital Asset Definition (e.g. money)
asset = Asset(data={'money': 'RMB'},
data_id='20170628150000',
divisible=True)
# Metadata Definition
metadata = {'planet': 'earth'}
# create trnsaction TODO : owners_before might be node_pubkey in v0.8.0
txi = Transaction.create([alice.public_key], [([alice.public_key], 100),
([alice.public_key], 100)],
metadata=metadata,
asset=asset)
print(" ")
print("1.tx_create asset id : alice-----money(",
tx.to_dict()['transaction']['asset']['id'], ")----->alice")
print("1.tx_create tx id : ", txi.to_dict()['id'])
# sign with alice's private key
txi = txi.sign([alice.private_key])
tx_id = txi.to_dict()['id']
# write to backlog
b = Bigchain()
print("1.tx_create db response : ", b.write_transaction(tx))
# wait 2 sec
sleep(delay)
##################################################### 3.TRANSFER
# inputs and asset [double spend]
cid = 1
condition = tx.to_dict()['transaction']['conditions'][cid]
inputs = Fulfillment.from_dict({
'fulfillment':
condition['condition']['details'],
'input': {
'cid': cid,
'txid': tx.to_dict()['id'],
},
'owners_before': [alice.public_key],
})
asset = Asset.from_dict(tx.to_dict()['transaction']['asset'])
# transfer
tx1 = Transaction.transfer([inputs], [([bob.public_key], 100)], asset)
print("3.tx_double asset id : alice-----money(",
tx1.to_dict()['transaction']['asset']['id'], ")----->bob")
print("3.tx_double tx id : ", tx1.to_dict()['id'])
# sign with alice's private key
tx1 = tx1.sign([alice.private_key])
tx1_id = tx1.to_dict()['id']
# write to backlog
b = Bigchain()
print("3.tx_double db response : ", b.write_transaction(tx1))
# wait 2 sec
sleep(delay)
# get tx by id
tx1 = b.get_transaction(tx1_id)
block = list(b.get_blocks_status_containing_tx(tx1_id).keys())[0]
votes = list(b.backend.get_votes_by_block_id(block))
votes_cast = [vote['vote']['is_block_valid'] for vote in votes]
election = b.get_blocks_status_containing_tx(tx1_id)
print("3.tx_transfer query : ", tx1)
print("3.tx_transfer block : ", block)
print("3. votes : ", votes)
print("3. votes_cast : ", votes_cast)
print("3. election : ", election)
print(" ")
# get tx by id
tx = b.get_transaction(tx_id)
print("freeze 90 asset tx2_id:" + tx.to_dict()['id'])
##################################################### 3.UTXO
# inputs and asset
utxo = b.get_outputs_filtered_not_include_freeze(alicepub, include_spent)
for u in utxo:
# print(u)
u.pop('details')
print('userA unspent asset:')
print(json.dumps(utxo, indent=4))
# print(json.load(utxo))
if __name__ == '__main__':
alice, bob = generate_keypair(), generate_keypair()
alicepublic_key = alice.public_key
aliceprivate_key = alice.private_key
bobpublic_key = bob.public_key
bobprivate_key = bob.private_key
include_spent = False
print("userA public key : ", alicepublic_key)
print("userA private key : ", aliceprivate_key)
create_transfer(alicepublic_key, aliceprivate_key, include_spent)
def create_transfer():
##################################################### 1.CREATE
# Cryptographic Identities Generation
alice, bob, tom = generate_keypair(), generate_keypair(), generate_keypair()
asset = Asset(data={"bicycle": {"manufacturer": "bkfab", "serial_number": "abcd1234"}})
metadata = {'planet': 'earth'}
tx = Transaction.create([alice.public_key], [([alice.public_key], 1)], metadata=metadata, asset=asset)
print(" ")
print("1.tx_create asset id : alice-----bicycle(", tx.to_dict()['transaction']['asset']['id'], ")----->alice")
print("1.tx_create tx id : ", tx.to_dict()['id'])
# sign with alice's private key
tx = tx.sign([alice.private_key])
tx_id = tx.to_dict()['id']
# write to backlog
b = Bigchain()
print("1.tx_create db response : ", b.write_transaction(tx))
# wait 4 sec
sleep(delay)
# get tx by id
tx = b.get_transaction(tx_id)
print("1.tx_create query : ", tx)
# print("tx1_id:"+tx.to_dict()['id'])
print(" ")
##################################################### 2.TRANSFER
# inputs and asset
cid = 0
condition = tx.to_dict()['transaction']['conditions'][cid]
inputs = Fulfillment.from_dict({
'fulfillment': condition['condition']['details'],
'input': {
'cid': cid,
'txid': tx.to_dict()['id'],
},
'owners_before': condition['owners_after'],
})
asset = Asset.from_dict(tx.to_dict()['transaction']['asset'])
# transfer
tx = Transaction.transfer([inputs], [([bob.public_key], 1)], asset)
print("2.tx_transfer asset id : alice-----bicycle(", tx.to_dict()['transaction']['asset']['id'], ")----->bob")
print("2.tx_transfer tx id : ", tx.to_dict()['id'])
print("2.tx_transfer tx : ", tx.to_dict())
print(" ")
# sign with alice's private key
tx = tx.sign([alice.private_key])
# man in the middle attack, then write to backlog
tx.conditions[0].owners_after = [tom.public_key]
print("3.tx_attack asset id : alice-----bicycle(", tx.to_dict()['transaction']['asset']['id'], ")----->tom")
print("3.tx_attack tx id : ", tx.to_dict()['id'])
print("3.tx_attack tx : ", tx.to_dict())
tx_id = tx.to_dict()['id']
b = Bigchain()
print("3.tx_attack db response : ", b.write_transaction(tx))
# wait 4 sec
sleep(delay)
# get tx by id
tx = b.get_transaction(tx_id)
print("3.tx_attack query : ", tx)
print(" ")
rat test - run all unnit and integration tests
rat help - print this message
'''
print(h)
if __name__ == '__main__':
import sys
if len(sys.argv) < 2 or sys.argv[1] == 'help':
print_help()
elif sys.argv[1] == 'generate':
assert(len(sys.argv) == 3)
keypath = sys.argv[2]
priv, pub = crypto.generate_keypair()
crypto.write_keypair(priv, pub, keypath)
elif sys.argv[1] == 'serve':
serve()
elif sys.argv[1] == 'register':
_, own_pub = crypto.read_keypair(get_conf()['user']['keypath'])
register(sys.argv[2], own_pub)
elif sys.argv[1] == 'ask':
if len(sys.argv) >= 4:
ask(sys.argv[2], sys.argv[3:len(sys.argv)])
else:
print('To query namserververs please provide your regex and their IPs.')
