import os,sys; sys.path.append(os.path.abspath(os.path.join(os.path.abspath(os.path.join(os.path.dirname(__file__),'..')),'..'))) from komrade import * from komrade.backend import * from komrade.backend.keymaker import * class Komrade(Caller): def __init__(self, name=None, passphrase=DEBUG_DEFAULT_PASSPHRASE): super().__init__(name=name,passphrase=passphrase) if SHOW_STATUS: from komrade.cli import CLI self.cli = CLI(name=name, komrade=self) self.boot(create=False) def boot(self,create=False): # Do I already have my keys? # yes? -- login keys = self.keychain() if keys.get('pubkey') and keys.get('privkey'): self.log('booted!') return True # If not, forge them -- only once! if not have_keys and create: self.get_new_keys() def exists_locally_as_contact(self): return self.pubkey and not self.privkey def exists_locally_as_Komrade(self): return self.pubkey and self.privkey def exists_on_server(self): answer = self.phone.ring_ring({ '_route':'does_username_exist', 'name':self.name }) self.log('answer??',answer) return answer # login? # def login(self): # if keys.get('pubkey') and keys.get('privkey') def register(self, name = None, passphrase = None, is_group=None, show_intro=0,show_body=True): # print('got name:',name) ## Defaults if name and not self.name: self.name=name if not name and self.name: name=self.name # if not name and not self.name: name='' # print('got name',name) ## 1) Have name? tolog='' if SHOW_STATUS and show_intro: self.name = name = self.cli.status_keymaker_part1(name) elif not name: self.name = name = input('\nHello, this is Komrade @') print('\nI would like to sign up for the socialist network revolution.',flush=True) do_pause() else: print(f'Hello, this is Komrade @{name}.\n\nI would like to sign up for the socialist network revolution.') do_pause() clear_screen() self.log(f'@Keymaker: Excellent. But to communicate with komrades securely,\nyou must first cut your public & private encryption keys. ') # do_pause() ## 2) Make pub public/private keys keypair = KomradeAsymmetricKey() pubkey,privkey = keypair.pubkey_obj,keypair.privkey_obj self.log(f'@Keymaker: I have cut for you a private and public asymmetric key pair\nusing the Elliptic Curve algorithm from Themis cryptography library:\n\n(1) {pubkey}\n\n(2) {privkey}{ART_KEY_PAIR}',clear=False,pause=True) ## 3) Have passphrase? if SHOW_STATUS and not passphrase: passphrase = self.cli.status_keymaker_part2(name,passphrase,pubkey,privkey,hasher,self) else: if not passphrase: passphrase = DEBUG_DEFAULT_PASSPHRASE while not passphrase: passphrase=getpass(f'@Keymaker: Enter a memorable password to encrypt your private key with: \n\n@{self.name}: ') clear_screen() ## 4) Get hashed password passhash = hasher(passphrase) self.log(f'''@Keymaker: I have replaced your password with a disguised, hashed version\nusing a salted SHA-256 algorithm from python's hashlib:\n\n\t{make_key_discreet_str(passhash)}''') ## 5) Encrypt private key privkey_decr = KomradeSymmetricKeyWithPassphrase(passphrase) privkey_encr = privkey_decr.encrypt(privkey.data) privkey_encr_obj = KomradeEncryptedAsymmetricPrivateKey(privkey_encr) self.log(f"@Keymaker: Store your private key on your device hardware ONLY\nas it was encrypted by your password-generated key:\n\n[Encrypted Private Key]\n({make_key_discreet_str(privkey_encr_obj.data_b64)})") ## 6) Test keychain works privkey_decr2 = KomradeSymmetricKeyWithPassphrase(passphrase) assert privkey_decr2.decrypt(privkey_encr) == privkey.data self._keychain['pubkey']=pubkey self._keychain['privkey_encr']=privkey_encr_obj # self._keychain['privkey_decr']=privkey_decr # we should be able to reassemble privkey now? # self.log('this is my keychain now:') assert 'privkey' in self.keychain() # self.log('My keychain now looks like:',dict_format(self.keychain())) ## 6) More narration? if SHOW_STATUS: self.cli.status_keymaker_part3(privkey,privkey_decr,privkey_encr,passphrase) ## 7) Save data to server data = { 'name':name, 'pubkey': pubkey.data, } self.log('@Keymaker: Store your public key both on your device hardware\nas well as register it with Komrade @Operator on the remote server:\n\n',dict_format(data,tab=2)) # ring operator # call from phone since I don't have pubkey on record on Op yet # self.log('my keychain:',self._keychain,pubkey,self.op._keychain) resp_msg_d = self.ring_ring( { 'name':name, 'pubkey': pubkey.data, }, route='register_new_user' ) if not resp_msg_d.get('success'): self.log(f'Registration failed. Message from operator was:\n\n{dict_format(resp_msg_d)}') return # otherwise, save things on our end self.log(f'Registration successful. Message from operator was:\n\n{dict_format(resp_msg_d)}') self.name=resp_msg_d.get('name') pubkey_b = resp_msg_d.get('pubkey') sec_login = resp_msg_d.get('secret_login') pubkey=self._keychain['pubkey']=KomradeAsymmetricPublicKey(pubkey_b) uri_id = b64enc(pubkey_b) self.crypt_keys.set( self.name, pubkey_b, prefix='/pubkey/') self.crypt_keys.set( uri_id, self.name, prefix='/name/') self.crypt_keys.set( uri_id, sec_login, prefix='/secret_login/' ) self.crypt_keys.set( uri_id, privkey_encr_obj.data, prefix='/privkey_encr/' ) self.log(f'''Now saving name and public key on local device:''') # save qr too: uri_id = b64enc(pubkey_b) qr_str=self.qr_str(uri_id) fnfn=self.save_uri_as_qrcode(uri_id) # self.log(f'saved public key as QR code to:\n {fnfn}\n\n{qr_str}') return resp_msg_d # done! self.log(f'Congratulations. Welcome, Komrade {self}.') @property def secret_login(self): return self.crypt_keys.get( self.pubkey.data_b64, prefix='/secret_login/' ) def login(self,passphrase=None): # check hardware if not self.pubkey: self.log('''Login impossible. I do not have this komrade's public key, much less private one.''') return if not self.privkey_encr: self.log('''Login impossible. I do not have this komrade's private key on this hardware.''') return # check password # while not passphrase: # from getpass import getpass # passphrase = getpass('@Keymaker: Enter password for {self} in order to decrypt the encrypted private key:\n\n') # assemble privkey? privkey = self.keychain(passphrase=passphrase).get('privkey') if not privkey: self.log('''Login impossible. I do not have this komrade's private key on this hardware.''') return # compose message msg = { 'name':self.name, 'pubkey':self.pubkey.data, 'secret_login':self.secret_login } # ask operator and get response resp_msg = self.ring_ring( msg, route='login' ) # get result self.log('Got result back from operator:',resp_msg) return resp_msg ## MEETING PEOPLE def find(self,someone): if type(someone)==str: return Komrade(name=someone) if type(someone)==bytes: return Komrade(pubkey=someone) self.log('what is type of someoen here?',type(someone)) return someone def meet(self,someone): # get person obj someone = self.find(someone) self.log('got someone =',someone,type(someone)) def ring_ring(self,msg,route=None,**y): if type(msg)==dict and not ROUTE_KEYNAME in msg: msg[ROUTE_KEYNAME]=route return super().ring_ring(msg,caller=self,**y) def send_msg_to(self,msg,to_whom): msg_e2e = self.compose_msg_to(msg,to_whom) msg.encrypt() {'_route':'deliver_msg_to', 'msg':msg} return self.ring_ring(msg) def test_register(): import random num = random.choice(list(range(0,1000))) botname=f'marx{str(num).zfill(3)}' marxbot = Komrade(botname) # marxbot=Komrade() marxbot.register(passphrase='spectre') if __name__=='__main__': test_register() # marx = Komrade('marx') # elon = Komrade('elon') # marx.register() # # elon.register() # # person.register() # # print(person.pubkey) # # elon.send_msg_to('youre dumb',marx) # #Caller('elon').ring_ring({'_route':'say_hello','msg':'my dumb message to operator'}) # # print(marx.exists_on_server())