def erase_all_knowledge(self): # snb self.snb = SensoryNeuralBlock() self.snb.save("persistent_memory/sight_snb.p", "persistent_memory/hearing_snb.p") # Relational Neural Block self.rnb = RelNetwork(100) RelNetwork.serialize(self.rnb, "persistent_memory/rnb.p") # Addition by memory network self.am_net = CulturalNetwork(100) CulturalNetwork.serialize(self.am_net, "persistent_memory/am_net.p") # Syllables net self.syllables_net = CulturalNetwork(100) CulturalNetwork.serialize(self.syllables_net, "persistent_memory/syllables_net.p") # Words net self.words_net = CulturalNetwork(100) CulturalNetwork.serialize(self.words_net, "persistent_memory/words_net.p") # Sight-Syllables rel network self.ss_rnb = RelNetwork(100) RelNetwork.serialize(self.ss_rnb, "persistent_memory/ss_rnb.p") # Geometric Neural Block self.gnb = GeometricNeuralBlock() GeometricNeuralBlock.serialize(self.gnb, "persistent_memory/gnb.p") ################ INTENTIONS #################################################################################### self.episodic_memory = EpisodicMemoriesBlock() EpisodicMemoriesBlock.serialize(self.episodic_memory, "persistent_memory/episodic_memory.p") self.decisions_block = DecisionsBlock() DecisionsBlock.serialize(self.decisions_block, "persistent_memory/decisions_block.p") self.internal_state = InternalState() InternalState.serialize(self.internal_state, "persistent_memory/internal_state.p") self.desired_state = InternalState([0.5,1,1]) InternalState.serialize(self.desired_state, "persistent_memory/desired_state.p")
def set_zero(self): s_pattern = self.s_knowledge_in.get_pattern() self.state = self.snb.recognize_sight(s_pattern) if self.state == "HIT": hearing_id = self._get_hearing_id_recognize() self.gnb.set_zero(hearing_id) GeometricNeuralBlock.serialize(self.gnb, "persistent_memory/gnb.p") return True return False
def set_zero(self): s_pattern = self.s_knowledge_in.get_pattern() self.state = self.snb.recognize_sight(s_pattern) if self.state == "HIT": self.hearing_id = self._get_hearing_id_recognize() self.gnb.set_zero(self.hearing_id) GeometricNeuralBlock.serialize(self.gnb, "gnb", self.project_id) return True return False
def create_kernel(self): # snb self.snb = SensoryNeuralBlock("no_data", "no_data", self.project_id) self.snb.save("snb_s", "snb_h", self.project_id, self.brain) # Relational Neural Block self.rnb = RelNetwork(100) RelNetwork.serialize(self.rnb, "rnb", self.project_id) # Addition by memory network self.am_net = CulturalNetwork(100) CulturalNetwork.serialize(self.am_net, "am_net", self.project_id) # Syllables net self.syllables_net = CulturalNetwork(100) CulturalNetwork.serialize(self.syllables_net, "syllables_net", self.project_id) # Words net self.words_net = CulturalNetwork(100) CulturalNetwork.serialize(self.words_net, "words_net", self.project_id) # Sight-Syllables rel network self.ss_rnb = RelNetwork(100) RelNetwork.serialize(self.ss_rnb, "ss_rnb", self.project_id) # Geometric Neural Block self.gnb = GeometricNeuralBlock() GeometricNeuralBlock.serialize(self.gnb, "gnb", self.project_id) ################ INTENTIONS #################################################################################### self.episodic_memory = EpisodicMemoriesBlock() EpisodicMemoriesBlock.serialize(self.episodic_memory, "episodic_memory", self.project_id) self.decisions_block = DecisionsBlock() DecisionsBlock.serialize(self.decisions_block, "decisions_block", self.project_id) self.internal_state = InternalState() InternalState.serialize(self.internal_state, "internal_state", self.project_id) self.desired_state = InternalState([0.75, 0.75, 0.75]) InternalState.serialize(self.desired_state, "desired_state", self.project_id)
def _clack_counting(self): hearing_id = self._get_hearing_id_recognize() self.gnb.clack(hearing_id) GeometricNeuralBlock.serialize(self.gnb, "persistent_memory/gnb.p") return
def __init__(self): grid_size = 16 # HEURISTICS: radius = (1/3)*2^(ENCODING_SIZE) # where ENCODING_SIZE is bit size of every pattern element (8 bits for us) radius = 24 # Calculate pattern size based on grid_size and size of a Nibble (4) pattern_size = pow(grid_size, 2) / 4 # Set neural network data size RbfNetwork.PATTERN_SIZE = pattern_size # Set neural network default radius RbfNetwork.DEFAULT_RADIUS = radius # Set pattern size in RBF knowledge RbfKnowledge.PATTERN_SIZE = pattern_size # If there are no persisten memory related files, create them if not os.path.isfile("persistent_memory/sight_snb.p"): self.erase_all_knowledge() # SNB self.snb = SensoryNeuralBlock("persistent_memory/sight_snb.p", "persistent_memory/hearing_snb.p") # Relational Neural Block self.rnb = RelNetwork.deserialize("persistent_memory/rnb.p") # Analytical neuron self.analytical_n = AnalyticalNeuron() # Addition by memory network self.am_net = CulturalNetwork.deserialize("persistent_memory/am_net.p") # Geometric Neural Block self.gnb = GeometricNeuralBlock.deserialize("persistent_memory/gnb.p") # Syllables net self.syllables_net = CulturalNetwork.deserialize( "persistent_memory/syllables_net.p") # Words net self.words_net = CulturalNetwork.deserialize( "persistent_memory/words_net.p") # Sight-Syllables rel network self.ss_rnb = RelNetwork.deserialize("persistent_memory/ss_rnb.p") # ################### INTENTIONS MODULES ######################################################################## self.episodic_memory = EpisodicMemoriesBlock.deserialize( "persistent_memory/episodic_memory.p") self.decisions_block = DecisionsBlock.deserialize( "persistent_memory/decisions_block.p") self.internal_state = InternalState.deserialize( "persistent_memory/internal_state.p") self.desired_state = InternalState.deserialize( "persistent_memory/desired_state.p") # Internal state "Ports" (Three components real valued vector) self._internal_state_in = None # Memory that stores short term bip inputs for making a decision self._intentions_short_term_memory = [] self._output_memory = None # ############################################################################################################### # _bbcc_words self._learning_words = False self._learning_syllables = False self._enable_bbcc = False # Output "ports" (related to senses) self.s_knowledge_out = None self.h_knowledge_out = None # Input "ports" (senses) self.s_knowledge_in = None self.h_knowledge_in = None self._working_domain = "ADDITION" self.state = "MISS"
class KernelBrainCemisid: ## Kernel contructor def __init__(self): grid_size = 16 # HEURISTICS: radius = (1/3)*2^(ENCODING_SIZE) # where ENCODING_SIZE is bit size of every pattern element (8 bits for us) radius = 24 # Calculate pattern size based on grid_size and size of a Nibble (4) pattern_size = pow(grid_size, 2) / 4 # Set neural network data size RbfNetwork.PATTERN_SIZE = pattern_size # Set neural network default radius RbfNetwork.DEFAULT_RADIUS = radius # Set pattern size in RBF knowledge RbfKnowledge.PATTERN_SIZE = pattern_size # If there are no persisten memory related files, create them if not os.path.isfile("persistent_memory/sight_snb.p"): self.erase_all_knowledge() # SNB self.snb = SensoryNeuralBlock("persistent_memory/sight_snb.p", "persistent_memory/hearing_snb.p") # Relational Neural Block self.rnb = RelNetwork.deserialize("persistent_memory/rnb.p") # Analytical neuron self.analytical_n = AnalyticalNeuron() # Addition by memory network self.am_net = CulturalNetwork.deserialize("persistent_memory/am_net.p") # Geometric Neural Block self.gnb = GeometricNeuralBlock.deserialize("persistent_memory/gnb.p") # Syllables net self.syllables_net = CulturalNetwork.deserialize( "persistent_memory/syllables_net.p") # Words net self.words_net = CulturalNetwork.deserialize( "persistent_memory/words_net.p") # Sight-Syllables rel network self.ss_rnb = RelNetwork.deserialize("persistent_memory/ss_rnb.p") # ################### INTENTIONS MODULES ######################################################################## self.episodic_memory = EpisodicMemoriesBlock.deserialize( "persistent_memory/episodic_memory.p") self.decisions_block = DecisionsBlock.deserialize( "persistent_memory/decisions_block.p") self.internal_state = InternalState.deserialize( "persistent_memory/internal_state.p") self.desired_state = InternalState.deserialize( "persistent_memory/desired_state.p") # Internal state "Ports" (Three components real valued vector) self._internal_state_in = None # Memory that stores short term bip inputs for making a decision self._intentions_short_term_memory = [] self._output_memory = None # ############################################################################################################### # _bbcc_words self._learning_words = False self._learning_syllables = False self._enable_bbcc = False # Output "ports" (related to senses) self.s_knowledge_out = None self.h_knowledge_out = None # Input "ports" (senses) self.s_knowledge_in = None self.h_knowledge_in = None self._working_domain = "ADDITION" self.state = "MISS" ## Sets a working domain for the bbcc protocol. It could be either "READING", "ADDITION", "COUNTING", "EPISODES" # or "INTENTIONS" # @param domain enum { "READING", "ADDITION", "COUNTING", "EPISODES", "INTENTIONS" } def set_working_domain(self, domain): if (domain != "READING" and domain != "ADDITION" and domain != "COUNTING" and domain != "EPISODES" and domain != "INTENTIONS"): return self._working_domain = domain ## Get bbcc protocol working domain # @retval working_domain enum { "READING", "ADDITION", "COUNTING", "EPISODES", "INTENTIONS" } def get_working_domain(self): return self._working_domain ## Set sight knowledge # @param knowledge RbfKnowledge def set_sight_knowledge_in(self, knowledge): self.s_knowledge_in = knowledge ## Get sight knowledge # @retval knowledge RbfKnowledge def get_sight_knowledge_in(self): return self.s_knowledge_in ## Set hearing knowledge # @param knowledge RbfKnowledge def set_hearing_knowledge_in(self, knowledge): self.h_knowledge_in = knowledge ## Get hearing knowledge # @retval knowledge RbfKnowledge def get_hearing_knowledge_in(self): return self.h_knowledge_in ## Get output sight knowledge (Thinking) # @retval knowledge RbfKnowledge vector def get_sight_knowledge_out(self): return self.s_knowledge_out ## Get output hearing knowledge (Thinking) # @retval knowledge RbfKnowledge vector def get_hearing_knowledge_out(self): return self.h_knowledge_out # ################## INTENTIONS CODE ################################################################################ ## Set internal state related to an input. For example, an apple would be related to somthing like *[B=1,C=0,F=0]* # (Note that this is not the machine's internal state) # @param states_vector Floats vector. For example, *[1.0,0.1,0.1]* def set_internal_state_in(self, states_vector): self._internal_state_in = states_vector ## Set internal state (Biology, Culture and Feelings) # @param states_vector: three components vector: [Biology, Culture, Feelings]. All components are in the real interval [0,1] # @return: True if state properly set, False in any other case. def set_internal_state(self, states_vector): state_correctly_set = self.internal_state.set_state(states_vector) if state_correctly_set: self.decisions_block.set_internal_state( self.internal_state.get_state()) InternalState.serialize(self.internal_state, "persistent_memory/internal_state.p") return state_correctly_set ## Get internal state # @retval internal_state InternalState. def get_internal_state(self): return self.internal_state ## Get internal state resulting from an experience and take the average with the current internal state # @param states_vector Floats vector, for example *[0.7, 0.5, 0.3]* def feed_internal_state(self, states_vector): state_correctly_fed = self.internal_state.average_state(states_vector) if state_correctly_fed: self.decisions_block.set_internal_state( self.internal_state.get_state()) InternalState.serialize(self.internal_state, "persistent_memory/internal_state.p") return state_correctly_fed ## Set desired state (Biology, Culture and Feelings) # @param states_vector Floats vector: [Biology, Culture, Feelings]. # All components are in the real interval [0,1] # @retval result Boolean. True if state properly set, False in any other case. def set_desired_state(self, states_vector): state_correctly_set = self.desired_state.set_state(states_vector) if state_correctly_set: self.decisions_block.set_desired_state( self.desired_state.get_state()) InternalState.serialize(self.desired_state, "persistent_memory/desired_state.p") return state_correctly_set ## Get desired state # @retval desired_state InternalState def get_desired_state(self): return self.desired_state #################################################################################################################### ## Disable bbcc protocol so that Check and Clack can be used as standalone actions def disable_bbcc(self): self._enable_bbcc = False ## Start bbcc protocol def bum(self): # Enable check and clack as a part of bbcc protocol # preventing their effect as standalone actions self._enable_bbcc = True # Clean outputs self.s_knowledge_out = [] self.h_knowledge_out = [] # If working in the domain of READING # transmit bum signal to words networks if self._working_domain == "READING": self._bum_words() # Transmit it to addition networks elif self._working_domain == "ADDITION": self._bum_addition() # Else, transmit it to counting net elif self._working_domain == "COUNTING": self._bum_counting() #################### INTENTIONS ################################################################################ # Else, episodic memory elif self._working_domain == "EPISODES": self._bum_episodes() # Intentions else: self._bum_intentions() ## Bip part of bbcc protocol (See bbcc protocol description) def bip(self): # If protocol is not enabled, do nothing if not self._enable_bbcc: return # Clean outputs self.s_knowledge_out = [] self.h_knowledge_out = [] # Recognize given sight pattern self.state = self.snb.recognize_sight( self.s_knowledge_in.get_pattern()) # If pattern is recognized, proceed with bbcc protocol if self.state == "HIT": # If currently working with words, send bip signal to words networks if self._working_domain == "READING": self._bip_words() # Send bip signal to addition networks (AM and GNB) elif self._working_domain == "ADDITION": self._bip_addition() # Else, transmit it to counting net elif self._working_domain == "COUNTING": self._bip_counting() # ################### INTENTIONS ################################################################################ # Else, episodic memory elif self._working_domain == "EPISODES": self._bip_episodes() else: self._bip_intentions() ## Check if there is knowledge associated with the given sequence of patterns from # bbcc protocol when self._enable_bbcc is True. Check if the Sensory Neural Block recognizes the # given pattern when self._enable_bbcc is False def check(self): # Clean outputs self.s_knowledge_out = [] self.h_knowledge_out = [] # Part of complete bbcc protocol if self._enable_bbcc: self.state = self.snb.recognize_sight( self.s_knowledge_in.get_pattern()) # If pattern is recognized, proceed with bbcc protocol if self.state == "HIT": if self._working_domain == "READING": self._check_words() # Send bip signal to addition networks (AM and GNB) elif self._working_domain == "ADDITION": self._check_addition() #################### INTENTIONS ################################################################################ # Else, episodic memory elif self._working_domain == "EPISODES": self._check_episodes() else: self._check_intentions() # Not part of complete bbcc protocol, just recognize else: self.recognize() ## Execute clack action of bbcc protocol when self._enable_bbcc is True or Learn a piece of RbfKnowledge # coming from the senses when self._enable_bbcc is False def clack(self): # Clean outputs self.s_knowledge_out = [] self.h_knowledge_out = [] if self._enable_bbcc: if self._working_domain == "READING": self._clack_words() # Send bip signal to addition networks (AM and GNB) elif self._working_domain == "ADDITION": self._clack_addition() # Else, transmit it to counting net elif self._working_domain == "COUNTING": self._clack_counting() #################### INTENTIONS ################################################################################ # Else, episodic memory elif self._working_domain == "EPISODES": self._clack_episodes() else: self._clack_intentions() else: self.learn() self._enable_bbcc = False ## Pass bum signal to syllables and words networks def _bum_words(self): self._learning_words = True self._learning_syllables = True self.words_net.bum() self.syllables_net.bum() ## Pass bum signal to addition networks def _bum_addition(self): # self.am_net.bum() self.gnb.set_operation("ADD") self.gnb.bum() ## Execute bip part of bbcc potocol in syllables and words networks def _bip_words(self): # Get id of neuron that recognized sight pattern sight_id = self.snb.snb_s.get_rneurons_ids()[0] # Get sight and hearing ids relationship from sight-hearing relational neural block s_h_rels = self.rnb.get_sight_rels(sight_id) # Get sight and syllables ids relationship from sight-syllables relational neural block s_syll_rels = self.ss_rnb.get_sight_rels(sight_id) # If at least one relationship was found between sight pattern and a hearing piece of # knowledge and the kernel is currently learning syllables, execute bip just in the # syllables net if len(s_h_rels) != 0 and self._learning_syllables: # Syllables hearing_id = s_h_rels[0].get_h_id() self.syllables_net.bip(hearing_id) # If no relation found, the kernel is not learning syllables but words else: self._learning_syllables = False # If at least one relationship was found between sight pattern and a syllable # and the kernel is currently learning syllables, execute bip just in the # syllables net if len(s_syll_rels) != 0 and self._learning_words: self._bbcc_words = True syll_hearing_id = s_syll_rels[0].get_h_id() self.words_net.bip(syll_hearing_id) # If no relation found, the kernel is not learning syllables but words else: self._learning_words = False # If the kernel is neither learning words nor learning syllables, # disable bbcc protocol if not self._learning_syllables and not self._learning_words: self._enable_bbcc = False ## Pass bip signal to addition networks def _bip_addition(self): hearing_id = self._get_hearing_id_recognize() # self.am_net.bip(hearing_id) self.gnb.bip(hearing_id) if len(self.gnb.addition_result) != 0: result = self.gnb.addition_result self.s_knowledge_out = [] self.h_knowledge_out = [] for digit_h_id in result: self.h_knowledge_out.append( self.snb.get_hearing_knowledge(digit_h_id, True)) digit_s_id = self.rnb.get_hearing_rels( digit_h_id)[0].get_s_id() self.s_knowledge_out.append( self.snb.get_sight_knowledge(digit_s_id, True)) ## Check if addition by memory network has a result related # to the operation given through the bbcc protocol def _check_addition(self): hearing_id = self._get_hearing_id_recognize() am_id = self.am_net.check(hearing_id) # If addition_by_memory doesn't have any knowledge related to the preceding bbc series, proceed with clack if am_id is None: self.state = "MISS" return # If it in fact has some knowledge related, show it hearing_id = self.am_net.get_tail_knowledge(am_id) # Get hearing knowledge related to recognized sight pattern from BNS self.h_knowledge_out = self.snb.get_hearing_knowledge(hearing_id, True) self._enable_bbcc = False ## Check if either syllables net or words net has a piece of knowledge related to # the given bbcc input sequence def _check_words(self): # Get id of neuron that recognized sight pattern sight_id = self.snb.snb_s.get_rneurons_ids()[0] # Get sight and hearing ids relationship from sight-hearing relational neural block s_h_rels = self.rnb.get_sight_rels(sight_id) # Get sight and syllables ids relationship from sight-syllables relational neural block s_syll_rels = self.ss_rnb.get_sight_rels(sight_id) # Syllables if len(s_h_rels) != 0 and self._learning_syllables: # Syllables hearing_id = s_h_rels[0].get_h_id() syll_id = self.syllables_net.check(hearing_id) # If syllables net does not have any knowledge related to the preceding bbc series, proceed with clack if syll_id is None: self._learning_words = False self.state = "MISS" return self.state = "HIT" hearing_knowledge = self.syllables_net.get_tail_knowledge(syll_id) sight_id = self.ss_rnb.get_hearing_rels(syll_id)[0].get_s_id() self.s_knowledge_out = self.snb.get_sight_knowledge(sight_id, True) self.h_knowledge_out = hearing_knowledge self._enable_bbcc = False self._learning_words = False # self._learning_syllables = False # Words if len(s_syll_rels) != 0 and self._learning_words: syll_hearing_id = s_syll_rels[0].get_h_id() word_id = self.words_net.check(syll_hearing_id) # If word net doesn't have any knowledge related to the preceding bbc series, proceed with clack if word_id is None: self.state = "MISS" return self.s_knowledge_out = self.words_net.get_tail_knowledge(word_id) self._enable_bbcc = False self._learning_syllables = False # self._learning_words = False ## Get id of hearing neuron from id of sight neuron by using a relational network def _get_hearing_id_recognize(self): # Obtain id of neuron that recognized sight pattern sight_id = self.snb.snb_s.get_rneurons_ids()[0] # Obtain sight and hearing ids relationship from relational neural block sight_rel = self.rnb.get_sight_rels(sight_id)[0] # Get hearing id from relation return sight_rel.get_h_id() # Esto puede ser puesto en un modulo de 'utility functions' @staticmethod def is_null_pattern(pattern): for element in pattern: if element != 0: return False return True ## Learn words or syllables related to given bbcc sequence def _clack_words(self): if self._learning_words: sight_pattern = self.s_knowledge_in.get_pattern() sight_class = "None" sight_knowledge = RbfKnowledge(sight_pattern, sight_class) self.words_net.clack(sight_knowledge) CulturalNetwork.serialize(self.words_net, "persistent_memory/words_net.p") self._learning_words = False else: hearing_pattern = self.h_knowledge_in.get_pattern() hearing_class = self.h_knowledge_in.get_class() hearing_knowledge = RbfKnowledge(hearing_pattern, hearing_class) self.syllables_net.clack(hearing_knowledge) CulturalNetwork.serialize(self.syllables_net, "persistent_memory/syllables_net.p") syll_hearing_id = self.syllables_net.get_last_clack_id() sight_pattern = self.s_knowledge_in.get_pattern() # Recognize if self.snb.recognize_sight(sight_pattern) == "HIT": sight_id = self.snb.snb_s.get_rneurons_ids()[0] else: sight_class = "syll_" + str(syll_hearing_id) sight_knowledge = RbfKnowledge(sight_pattern, sight_class) self.snb.learn_sight(sight_knowledge) sight_id = self.snb.snb_s.get_last_learned_id() self.snb.save("persistent_memory/sight_snb.p", "persistent_memory/hearing_snb.p") # Learn relation in new net rel_knowledge = RelKnowledge(syll_hearing_id, sight_id) self.ss_rnb.learn(rel_knowledge) RelNetwork.serialize(self.ss_rnb, "persistent_memory/ss_rnb.p") self._learning_syllables = False ## Learn addition related to given bbcc sequence def _clack_addition(self): s_pattern = self.s_knowledge_in.get_pattern() self.state = self.snb.recognize_sight(s_pattern) if self.state == "HIT": hearing_id = self._get_hearing_id_recognize() self.am_net.clack(hearing_id) CulturalNetwork.serialize(self.am_net, "persistent_memory/am_net.p") ## Recognize either hearing or sight patterns. def recognize(self): # Get sight and hearing patterns s_pattern = self.s_knowledge_in.get_pattern() h_pattern = self.h_knowledge_in.get_pattern() # If no patterns or both patterns given, do nothing if (KernelBrainCemisid.is_null_pattern(s_pattern) and KernelBrainCemisid.is_null_pattern(h_pattern) or not KernelBrainCemisid.is_null_pattern(s_pattern) and not KernelBrainCemisid.is_null_pattern(h_pattern)): return # If hearing pattern given, recognize hearing elif KernelBrainCemisid.is_null_pattern(s_pattern): self.hearing_recognize() # If sight pattern given, recognize sight else: self.sight_recognize() ## Recognize hearing pattern def hearing_recognize(self): pattern = self.h_knowledge_in.get_pattern() self.state = self.snb.recognize_hearing(pattern) if self.state == "HIT": self.h_knowledge_out = self.snb.get_hearing_knowledge(pattern) # ################ INTENTIONS ############################################################################### # Get hearing id of recognizing neuron hearing_id = self.snb.snb_h.get_rneurons_ids()[0] # Get memory related to hearing id memory = self.episodic_memory.retrieve_exact_memory([hearing_id]) # Get bcf related to memory memory_bcf = memory.get_tail_knowledge().get_state() # Memory's bcf affects internal state self.feed_internal_state(memory_bcf) ## Recognize sight pattern def sight_recognize(self): pattern = self.s_knowledge_in.get_pattern() self.state = self.snb.recognize_sight(pattern) if self.state == "HIT": # Obtain id of neuron that recognized sight pattern sight_id = self.snb.snb_s.get_rneurons_ids()[0] # Obtain sight and hearing ids relationship from relational neural block sight_rel = self.rnb.get_sight_rels(sight_id)[0] # Get hearing id from relation hearing_id = sight_rel.get_h_id() # Put hearing knowledge in output port self.h_knowledge_out = self.snb.get_hearing_knowledge( hearing_id, True) # Put sight knowledge in output port self.s_knowledge_out = self.snb.get_sight_knowledge(sight_id, True) ################# INTENTIONS ############################################################################### # Get memory related to hearing id memory = self.episodic_memory.retrieve_exact_memory([hearing_id]) # Get bcf related to memory memory_bcf = memory.get_tail_knowledge().get_state() # Memory's bcf affects internal state self.feed_internal_state(memory_bcf) elif self.state == "DIFF": # Get ids os sight neurons that recognized the pattern ids_recognize = self.snb.snb_s.get_rneurons_ids() # Initialize a vector of relational knowledge rel_knowledge_vector = [] # Fill the vector with the relational knowledge of neurons that recognized the pattern for neuron_id in ids_recognize: rel_knowledge_vector += self.rnb.get_sight_rels(neuron_id) # Get hearing id from analytical neural block hearing_id = self.analytical_n.solve_ambiguity( rel_knowledge_vector) # Sight knowledge sight_knowledge = RbfKnowledge(pattern, str(hearing_id)) # Learn self.snb.learn_sight(sight_knowledge) # Get sight id sight_id = self.snb.snb_s.get_last_learned_id() # Learn relation rel_knowledge = RelKnowledge(hearing_id, sight_id) self.rnb.learn(rel_knowledge) # Try to recognize once again self.sight_recognize() ## Learn patterns def learn(self): # CORREGIR PARA QUE FUNCIONE CUANDO EL PATRON DEL HEARING NO SE APRENDE SINO QUE YA SE CONOCE self.snb.learn(self.h_knowledge_in, self.s_knowledge_in.get_pattern()) learned_ids = self.snb.get_last_learned_ids() rel_knowledge = RelKnowledge(learned_ids[0], learned_ids[1]) self.rnb.learn(rel_knowledge) RelNetwork.serialize(self.rnb, "persistent_memory/rnb.p") self.snb.save("persistent_memory/sight_snb.p", "persistent_memory/hearing_snb.p") ################ INTENTIONS #################################################################################### # New learned item will produce changes in internal state self.feed_internal_state(self._internal_state_in) # New learned item and passed internal state should be related as an episode internal_state_in = InternalState(self._internal_state_in) self.episodic_memory.bum() self.episodic_memory.check(learned_ids[1]) self.episodic_memory.clack(internal_state_in) EpisodicMemoriesBlock.serialize(self.episodic_memory, "persistent_memory/episodic_memory.p") ################################################################################################################ ## Erase all knowlege. Get to a *tabula rasa* state. def erase_all_knowledge(self): # snb self.snb = SensoryNeuralBlock() self.snb.save("persistent_memory/sight_snb.p", "persistent_memory/hearing_snb.p") # Relational Neural Block self.rnb = RelNetwork(100) RelNetwork.serialize(self.rnb, "persistent_memory/rnb.p") # Addition by memory network self.am_net = CulturalNetwork(100) CulturalNetwork.serialize(self.am_net, "persistent_memory/am_net.p") # Syllables net self.syllables_net = CulturalNetwork(100) CulturalNetwork.serialize(self.syllables_net, "persistent_memory/syllables_net.p") # Words net self.words_net = CulturalNetwork(100) CulturalNetwork.serialize(self.words_net, "persistent_memory/words_net.p") # Sight-Syllables rel network self.ss_rnb = RelNetwork(100) RelNetwork.serialize(self.ss_rnb, "persistent_memory/ss_rnb.p") # Geometric Neural Block self.gnb = GeometricNeuralBlock() GeometricNeuralBlock.serialize(self.gnb, "persistent_memory/gnb.p") ################ INTENTIONS #################################################################################### self.episodic_memory = EpisodicMemoriesBlock() EpisodicMemoriesBlock.serialize(self.episodic_memory, "persistent_memory/episodic_memory.p") self.decisions_block = DecisionsBlock() DecisionsBlock.serialize(self.decisions_block, "persistent_memory/decisions_block.p") self.internal_state = InternalState() InternalState.serialize(self.internal_state, "persistent_memory/internal_state.p") self.desired_state = InternalState([0.5, 1, 1]) InternalState.serialize(self.desired_state, "persistent_memory/desired_state.p") # GEOMETRIC NEURAL BLOCK RELATED METHODS # Set some already learned pattern as the addition operator def set_add_operator(self): s_pattern = self.s_knowledge_in.get_pattern() self.state = self.snb.recognize_sight(s_pattern) if self.state == "HIT": hearing_id = self._get_hearing_id_recognize() self.gnb.set_add_operator(hearing_id) GeometricNeuralBlock.serialize(self.gnb, "persistent_memory/gnb.p") return True return False # Set some already learned pattern as the equal sign def set_equal_sign(self): s_pattern = self.s_knowledge_in.get_pattern() self.state = self.snb.recognize_sight(s_pattern) if self.state == "HIT": hearing_id = self._get_hearing_id_recognize() self.gnb.set_equal_sign(hearing_id) GeometricNeuralBlock.serialize(self.gnb, "persistent_memory/gnb.p") return True return False ## Set some already learned pattern as the zero number def set_zero(self): s_pattern = self.s_knowledge_in.get_pattern() self.state = self.snb.recognize_sight(s_pattern) if self.state == "HIT": hearing_id = self._get_hearing_id_recognize() self.gnb.set_zero(hearing_id) GeometricNeuralBlock.serialize(self.gnb, "persistent_memory/gnb.p") return True return False ## Start counting in order to make the geometric neural net grow def _bum_counting(self): self.gnb.set_operation("COUNT") self.gnb.bum() return ## Pass bip signal to Geometric Neural Block def _bip_counting(self): self.gnb.bip() return ## Pass clack signal to Geometric Neural Block def _clack_counting(self): hearing_id = self._get_hearing_id_recognize() self.gnb.clack(hearing_id) GeometricNeuralBlock.serialize(self.gnb, "persistent_memory/gnb.p") return # ######################### INTENTIONS ############################################################################## ## Pass bum signal to episodic memory def _bum_episodes(self): self.episodic_memory.bum() ## Pass bip signal to episodic memory def _bip_episodes(self): hearing_id = self._get_hearing_id_recognize() self.episodic_memory.bip(hearing_id) ## Check if epsodic memory network has a result related # to the operation given through the bbcc protocol def _check_episodes(self): hearing_id = self._get_hearing_id_recognize() em_id = self.episodic_memory.check(hearing_id) # If doesn't have any knowledge related to the preceding bbc series, proceed with clack if em_id is None: self.state = "MISS" return # Get bcf related to episode episode_bcf = self.episodic_memory.get_tail_knowledge( em_id).get_state() # Memory's bcf affects internal state self.feed_internal_state(episode_bcf) # Disable bbcc self._enable_bbcc = False ## Pass clack signal to episodic memory def _clack_episodes(self): episode_bcf = BiologyCultureFeelings(self.internal_state.get_state()) self.episodic_memory.clack(episode_bcf) EpisodicMemoriesBlock.serialize(self.episodic_memory, "persistent_memory/episodic_memory.p") ## Pass bum signal to intentions short term memory (Alternatives) def _bum_intentions(self): self._intentions_short_term_memory = [] return ## Pass bip signal to intentions short term memory def _bip_intentions(self): hearing_id = self._get_hearing_id_recognize() self._intentions_short_term_memory.append(hearing_id) return ## Pass check signal to intentions in order to make a decision def _check_intentions(self): # Get memories memories = self.episodic_memory.retrieve_memories( self._intentions_short_term_memory) self.decisions_block.set_desired_state(self.desired_state) self.decisions_block.set_internal_state(self.internal_state) self.decisions_block.set_input_memories(memories) self._output_memory = self.decisions_block.get_output_memory() # Obtain sight and hearing ids relationship from relational neural block hearing_id = self._output_memory.group[0].get_knowledge() hearing_rel = self.rnb.get_hearing_rels(hearing_id)[0] # Get hearing id from relation sight_id = hearing_rel.get_s_id() # Put hearing knowledge in output port self.h_knowledge_out = self.snb.get_hearing_knowledge(hearing_id, True) # Put sight knowledge in output port self.s_knowledge_out = self.snb.get_sight_knowledge(sight_id, True) return ## Pass clack signal to intentions in order to feed back results of decision (InternalState) def _clack_intentions(self): self.feed_internal_state(self._internal_state_in) self.decisions_block.conscious_block.feedback(self.internal_state) ## DecisionsBlock.serialize(self.decisions_block, "persistent_memory/decisions_block.p") return
def _clack_counting(self): hearing_id = self._get_hearing_id_recognize() self.gnb.clack(hearing_id) GeometricNeuralBlock.serialize(self.gnb, "gnb", self.project_id) return
def __init__(self, user, project, frontend_request): grid_size = 16 # HEURISTICS: radius = (1/3)*2^(ENCODING_SIZE) # where ENCODING_SIZE is bit size of every pattern element (8 bits for us) radius = 24 # Calculate pattern size based on grid_size and size of a Nibble (4) pattern_size = pow(grid_size, 2) / 4 # Set neural network data size RbfNetwork.PATTERN_SIZE = pattern_size # Set neural network default radius RbfNetwork.DEFAULT_RADIUS = radius # Set pattern size in RBF knowledge RbfKnowledge.PATTERN_SIZE = pattern_size # If there are no persisten memory related files, create them self.user = user self.hearing_id = -1 if frontend_request == "CREATE": self.brain = brain(user=self.user, name=project) self.brain.save() self.project_id = self.brain.id self.project_name = project self.create_kernel() self.message = 'the brain has been created successfully, the id is ' + str( self.project_id) if frontend_request == "LOAD": self.project_id = project # SNB self.snb = SensoryNeuralBlock("snb_s", "snb_h", self.project_id) #print(self.snb.snb_h.__dict__) #for i in self.snb.snb_h.neuron_list: #if i._knowledge!= None: #print(i._knowledge) # Relational Neural Block self.rnb = RelNetwork.deserialize("rnb", self.project_id) #print(self.rnb.__dict__) #for i in self.rnb.neuron_list: #if i._knowledge!= None: #print(i.__dict__) #print(i._knowledge.__dict__) # Addition by memory network self.am_net = CulturalNetwork.deserialize("am_net", self.project_id) #print(self.am_net.__dict__) #for i in self.am_net.group_list: #if i._knowledge!= None: #print(i.__dict__) # Geometric Neural Block self.gnb = GeometricNeuralBlock.deserialize("gnb", self.project_id) #print(self.gnb.__dict__) #for i in self.gnb._addition_structure.neurons: #if i._knowledge!= None: #print(i.__dict__) # Syllables net self.syllables_net = CulturalNetwork.deserialize( "syllables_net", self.project_id) #print(self.syllables_net.__dict__) #for i in self.syllables_net.group_list: #if i._knowledge!= None: #print(i.__dict__) # Words net self.words_net = CulturalNetwork.deserialize( "words_net", self.project_id) #print(self.words_net.__dict__) #for i in self.words_net.group_list: #if i._knowledge!= None: #print(i.__dict__) # Sight-Syllables rel network self.ss_rnb = RelNetwork.deserialize("ss_rnb", self.project_id) #print(self.ss_rnb.__dict__) # for i in self.ss_rnb.neuron_list: # if i._knowledge!= None: # print(i._knowledge.__dict__) #################### INTENTIONS MODULES ######################################################################## self.episodic_memory = EpisodicMemoriesBlock.deserialize( "episodic_memory", self.project_id) #print(self.episodic_memory.__dict__) #for i in self.episodic_memory.group_list: #print(i.__dict__) #for k in i.group: #print(k.__dict__) # if isinstance(k._knowledge, int): # asd=int(k._knowledge) # print(asd) # else: # print(k._knowledge.__dict__) self.decisions_block = DecisionsBlock.deserialize( "decisions_block", self.project_id) #print(self.decisions_block.__dict__) #print(self.decisions_block.conscious_block.decision_prediction_block.predictive_net.__dict__) self.internal_state = InternalState.deserialize( "internal_state", self.project_id) #print('internal',self.internal_state.__dict__) self.desired_state = InternalState.deserialize( "desired_state", self.project_id) #print('desired',self.desired_state.__dict__) self.message = "BRAIN SUCCESFULLY LOADED" ################################################# NON-deserialize data################ # Analytical neuron self.analytical_n = AnalyticalNeuron() #print(self.analytical_n.__dict__) # Internal state "Ports" (Three components real valued vector) self._internal_state_in = None # Memory that stores short term bip inputs for making a decision self._intentions_short_term_memory = [] self._output_memory = None # ############################################################################################################### # _bbcc_words self._learning_words = False self._learning_syllables = False self._enable_bbcc = False # Output "ports" (related to senses) self.s_knowledge_out = None self.h_knowledge_out = None # Input "ports" (senses) self.s_knowledge_in = None self.h_knowledge_in = None self._working_domain = "ADDITION" self.state = "MISS"