コード例 #1
0
    def __init__(self):

        # Initiate the constructor of the parent comms class
        self.channels = [comms(S_PORT[i]) for i in range(CONNECTIONS)]

        # Instantiate the RSA signature/verification object
        self.RSA = RSA_encrypt()

        # Select the jobs that will be run when instantiated
        self.start_jobs = [{
            'func': self.clear_transactions,
            'args': None,
            'info': 'New transaction sheet'
        }, {
            'func': self.mine,
            'args': None,
            'info': 'Start the mining program'
        }, {
            'func': self.message_receiver,
            'args': None,
            'info': 'Pull the messages from the in data queue'
        }, {
            'func': self.transaction_gen,
            'args': None,
            'info': 'Randomly generate transactions'
        }]

        # Add the inititate server tasks to the start jobs
        for i in range(CONNECTIONS):
            init = {
                'func': self.channels[i].init_server,
                'args': None,
                'info': 'Start the broadcast server worker'
            }
            start = {
                'func': self.channels[i].start_client,
                'args': (CLIENT[i], R_PORT[i]),
                'info': 'Start the client worker'
            }

            self.start_jobs.insert(0, start)
            self.start_jobs.insert(0, init)

        # Make the worker threads
        self.create_workers()
        self.create_jobs()
コード例 #2
0
    p = 0
    primes = generate_primes(2, int(math.sqrt(n)))
    for prime in primes:
        if n % prime == 0:
            p = prime
            break
    return {'p': p, 'q': (n / p)}


# Oppgave a)
beskjed = "heisann"
n = 216541799
e = 241

T = string_to_num(beskjed)
U = RSA_encrypt(n, e, T)

# Oppgave b)
# Vi kan bruke Erastostenes' såld til å knekke RSA med den offentlige nøkkelen(n,e).
# Siden n er produktet av to primtall, hvor det ene tallet er mindre en roten av n,
# og det andre er større. Med det kan vi generere en liste av primtal fra 2 til
# roten av n, og iterere gjennom den. Vi sjekker da om n er delelig på ett av
# primtallene, hvis divisjonen går opp har vi funnet p. For å finne q må vi ta n/p.

# Oppgave c)
prim = prim(n)

# Oppgave d)
if not check_key(prim['p'], prim['q'], e):
    print("Check_key er false")
    exit(0)
conn, addr = s.accept()
print("Received connection from ", addr[0], "(", addr[1], ")\n")

s_name = conn.recv(1024)
s_name = s_name.decode()
print(s_name, "has connected to the chat room\nEnter [e] to exit chat room\n")
conn.send(name.encode())

# receive client's n and public key
n = int(conn.recv(1024).decode())
public_key = int(conn.recv(1024).decode())

# GOST key
GOST_key = 0x1111222233334444555566667777888899990000aaaabbbbccccddddeeeeffff
# encrypted GOST key using RSA encryption with client's public key
encrypted_key = RSA_encrypt(GOST_key, public_key, n)

while True:
    message = input(str("Me : "))
    if message == "[e]":
        message = "Left chat room!"
        conn.send(message.encode())
        print("\n")
        break

    # text = fitted text to use GOST with # my_GOST = GOST object
    text, my_GOST = GOST_init(message, GOST_key)

    # encrypt message with GOST
    message = GOST_encrypt(text, my_GOST)
    encrypt_msg = " ".join(message)
コード例 #4
0
from RSA import RSA_encrypt, eratosthenes, gcd, check_key, mult_inverse, powermod, powermod2
from pca import meanCenter, standardize, pca
from regression import linearRegression, quadraticRegression, cubicRegression

# Oppgave 1 RSA

# a) Kodet beskjed = BERGEN

# b) Kod melding = [7040899,18090405]

# c)

t = [7040899, 18090405]
n = 160169311
e = 1737
u = RSA_encrypt(n, e, t)
print(u)

# Krypert melding = [58822763, 79142533]

# d)

qn = int(sqrt(n))
liste = eratosthenes(qn)
for i in liste:
    if n % i == 0:
        p = i

q = n // p
print(p, q)
コード例 #5
0
class crypto_miner():
    def __init__(self):

        # Initiate the constructor of the parent comms class
        self.channels = [comms(S_PORT[i]) for i in range(CONNECTIONS)]

        # Instantiate the RSA signature/verification object
        self.RSA = RSA_encrypt()

        # Select the jobs that will be run when instantiated
        self.start_jobs = [{
            'func': self.clear_transactions,
            'args': None,
            'info': 'New transaction sheet'
        }, {
            'func': self.mine,
            'args': None,
            'info': 'Start the mining program'
        }, {
            'func': self.message_receiver,
            'args': None,
            'info': 'Pull the messages from the in data queue'
        }, {
            'func': self.transaction_gen,
            'args': None,
            'info': 'Randomly generate transactions'
        }]

        # Add the inititate server tasks to the start jobs
        for i in range(CONNECTIONS):
            init = {
                'func': self.channels[i].init_server,
                'args': None,
                'info': 'Start the broadcast server worker'
            }
            start = {
                'func': self.channels[i].start_client,
                'args': (CLIENT[i], R_PORT[i]),
                'info': 'Start the client worker'
            }

            self.start_jobs.insert(0, start)
            self.start_jobs.insert(0, init)

        # Make the worker threads
        self.create_workers()
        self.create_jobs()

# -------------------------- Main thread function -------------------------- #

    def main_thread(self):
        while True:
            # Send a message
            test_msg = str({
                'time': str(datetime.now()),
                'type': 'print_msg',
                'info': 'Routine message sent from ' + ID,
                'ID': ID
            })
            send_msg = {
                'func': self.broadcast,
                'args': test_msg,
                'info': 'Message from task issuer'
            }
            g_var.task_queue.put(send_msg)

            # Send a message - update the ID status
            ID_msg = str({
                'time': str(datetime.now()),
                'type': 'ID',
                'info': {
                    'pk_e': self.RSA.pk_e,
                    'pk_n': self.RSA.pk_n
                },
                'ID': ID
            })
            send_msg = {
                'func': self.broadcast,
                'args': ID_msg,
                'info': 'Message from task issuer'
            }
            g_var.task_queue.put(send_msg)

            # Wait before starting the loop again
            sleep(TASKRELOAD)

# -------------------------- Receive msg functions ------------------------- #

    def message_receiver(self):
        while True:
            msg = g_var.input_data_queue.get()
            if msg['type'] == 'print_msg':
                print(msg['info'])

            elif msg['type'] == 'transaction':
                print('Recieved a transaction: ' + msg['trans'] +
                      '  signed: ' + str(msg['signature'] != None))
                if self.verify_transaction(msg['trans'], msg['signature'],
                                           msg['ID']):
                    self.add_transaction(msg['trans'], msg['signature'])

            elif msg['type'] == 'ID':
                g_var.IDS.update({
                    msg['ID']: {
                        'n': msg['info']['pk_n'],
                        'e': msg['info']['pk_e']
                    }
                })
                print('Updated ID for ' + msg['ID'])

            elif msg['type'] == 'new_block':
                block_dict = ast.literal_eval(msg['block'])
                if self.block_verification(block_dict):
                    self.add_new_block(block_dict)

            sleep(MSGRELOAD)

# -------------------------- Receive msg functions ------------------------- #

    def transaction_gen(self):
        while True:
            num = random.randint(1, 100)
            trans = 'A -> B ' + str(num)
            signature = self.RSA.sign(self.sha256_hash(trans))
            msg = {
                'time': str(datetime.now()),
                'type': 'transaction',
                'info': 'Random transaction',
                'ID': ID,
                'trans': trans,
                'signature': signature
            }
            send_trans = {
                'func': self.broadcast,
                'args': msg,
                'info': 'Random transaction'
            }

            print('New transaction: ' + msg['trans'] + '  signed: ' +
                  str(msg['signature'] != None))
            self.add_transaction(msg['trans'], msg['signature'])
            g_var.task_queue.put(send_trans)

            sleep(random.randint(1, TRANSGENFREQ))

# -------------------------- Block chain organier -------------------------- #

    def push_block(self, header):
        block = self.build_new_block(header)
        block_msg = {
            'time': str(datetime.now()),
            'type': 'new_block',
            'info': 'New block',
            'ID': ID,
            'block': str(block)
        }

        self.broadcast(str(block_msg))
        self.add_new_block(block)

    def build_new_block(self, header):
        block = {}
        block['header'] = header
        block['transactions'] = g_var.current_trans

        return block

    def get_current_header(self):
        header = {}
        header['info'] = 'Version 5, Creator: ' + ID
        header['prev_block_hash'] = self.sha256_hash(
            g_var.blockchain[-1]['header'])
        header['merkle_root'] = self.merkle_root(g_var.current_trans)
        header['time'] = str(datetime.now())
        header['difficulty'] = NUMZEROS

        return header

    def block_verification(self, block):
        # Check that the proof of work is valid
        if not self.right_key(str(block['header'])):
            print('Invalid proof of work - block rejected')
            return False

        # Check that the previous block hash is correct
#      print( block['header']['prev_block_hash'],
#            self.sha256_hash(g_var.blockchain[-1]['header']))


        if not block['header']['prev_block_hash'] ==  \
            self.sha256_hash(g_var.blockchain[-1]['header']):
            print('Different previous hash - fork created')

            # Check where this block attaches to the established blockchain
            for i in range(2, min(len(g_var.blockchain), FORKBLOCKBACK)):
                if not block['header']['prev_block_hash'] == \
                    self.sha256_hash(g_var.blockchain[-i]['header']):
                    print(f'Fork created, {i} blocks ago')

                    for fork in g_var.fork:
                        if block['header']['prev_block_hash'] == \
                            self.sha256_hash(fork['block'][-1]['header']):
                            fork['block'].append(block)
                    else:
                        g_var.fork.append({'block': [block], 'root': i - 1})

                    break

            # Check to see if we should take on this fork
            try:
                dels = []
                for i in range(len(g_var.fork)):
                    if len(g_var.fork[i]['block']) > g_var.fork[i]['root']:
                        self.replace_blockchain(g_var.fork[i])
                        dels.append(i)

                # Delete this fork
                dels.reverse()
                for i in dels:
                    g_var.fork.pop(i)
            except Exception as error:
                print('Error: ' + str(error))

            return False

        print('Block verification successful...\n')
        return True

    def add_new_block(self, block):
        print(
            ' ----------------------------- New block added ----------------------------- '
        )
        g_var.blockchain.append(block)
        self.update_fork_roots()
        self.write_to_file()
        self.clear_transactions()

    def add_transaction(self, transaction, signature):
        g_var.current_trans.append((transaction, signature))

    def verify_transaction(self, trans, signature, ID):
        try:
            n = g_var.IDS[ID]['n']
            e = g_var.IDS[ID]['e']
            plaintext = self.RSA.verify(signature, e, n)
            trans_hash = self.sha256_hash(trans)
            if plaintext == trans_hash:
                print('Transaction verified...')
                return True
            else:
                print('Invalid signature...')
                print(plaintext, trans_hash)
                return False
        except:
            print('Do not have the ID to verify transaction - allowing')
            return True

    def clear_transactions(self):
        g_var.current_trans = []

        # Reward to the miner
        g_var.current_trans.append(f'Miner {ID} gets {REWARD}')

    def replace_blockchain(self, fork):
        print('Accepting blockchain fork - ' + str(len(fork['block'])) +
              ' replaced \n')
        print(
            ' ----------------------------- New block added ----------------------------- '
        )
        for i in range(1, fork['root'] + 1):
            g_var.blockchain[-i] = fork['block'][-i]

    def update_fork_roots(self):
        dels = []
        for i in range(len(g_var.fork)):
            g_var.fork[i]['root'] += 1

            # See if we can remove the fork by checking its length
            if g_var.fork[i]['root'] > len(g_var.fork[i]['block']):
                dels.append(i)

        # Delete the required forks
        dels.reverse()
        for i in dels:
            g_var.fork.pop(i)

    def write_to_file(self):
        with open(FILENAME, 'w') as file:
            file.write(str(g_var.blockchain))

# ---------------------------- Broadcast program --------------------------- #

# Wrapper function to broadcast to all clients sequentially

    def broadcast(self, msg):
        for i in range(CONNECTIONS):
            self.channels[i].broadcast_msg(msg)

# ------------------------------ Miner program ----------------------------- #

    def mine(self):
        while True:
            header = self.get_current_header()
            nonce = {'nonce': random.randint(1, MAXNUM)}
            header.update(nonce)

            if self.right_key(str(header)):

                # Put a task on the task queue
                task = {
                    'func': self.push_block,
                    'args': header,
                    'info': 'New key found'
                }
                g_var.task_queue.put(task)

    def right_key(self, key):
        key = str.encode(key)
        result = hashlib.sha256(key)

        if result.hexdigest().startswith(START):
            return True
        else:
            return False

    def sha256_hash(self, string):
        string = str.encode(str(string))
        return str(hashlib.sha256(string).hexdigest())

    def merkle_root(self, trans):
        #      print(trans)
        if len(trans) > 1 and type(trans) == list:
            #          print(trans, trans[:int(len(trans)/2)], trans[int(len(trans)/2):])
            trans =  self.merkle_root(trans[:int(len(trans)/2)])        \
            + self.merkle_root(trans[int(len(trans)/2):])
            return self.sha256_hash(trans)
        else:
            if type(trans) == list:
                return self.sha256_hash(trans[0])
            else:
                return self.sha256_hash(trans)

# -------------------------- Thread worker setup -------------------------- #

# Create worker threads

    def create_workers(self):
        for _ in range(NUMBER_OF_THREADS):
            t = worker(self)
            t.daemon = True
            t.start()

    def create_jobs(self):
        for x in self.start_jobs:
            g_var.task_queue.put(x)
            sleep(0.5)