def main():
# Init loggers
log.set_level("fine")
log.set_sync(False)
agent_log.set_level("fine")
agent_log.set_sync(False)
ure_logger().set_level("fine")
ure_logger().set_sync(False)
# Set main atomspace
atomspace = AtomSpace()
set_default_atomspace(atomspace)
# Wrap environment
wrapped_env = CartPoleWrapper(env)
# Instantiate CartPoleAgent, and tune parameters
cpa = CartPoleAgent(wrapped_env)
cpa.delta = 1.0e-16
# Run control loop
while cpa.step():
time.sleep(0.1)
log.info("step_count = {}".format(cpa.step_count))
print(f"The final reward is {cpa.accumulated_reward}.")
def test_probabilities(self):
log.info("Statistics> test_probabilities")
# Add multiple data
for case in self.test_case:
self.provider.add_one_metadata(case)
# Add data's count
arr_2_gram_1 = [self.aaa, self.bbb]
arr_2_gram_2 = [self.aaa, self.ccc]
arr_3_gram_1 = [self.aaa, self.bbb, self.ccc]
self.provider.add_one_rawdata_count(arr_2_gram_1, 2)
self.provider.add_one_rawdata_count(arr_2_gram_2, 1)
self.provider.add_one_rawdata_count(arr_3_gram_1, 1)
# Calculate probabilities
PyProbabilityAtom().calculate_probabilities(self.provider)
statistic_data = self.provider.datamap_find(arr_2_gram_1)
assert_less_equal(statistic_data.probability, 0.667)
assert_greater_equal(statistic_data.probability, 0.665)
statistic_data = self.provider.datamap_find(arr_2_gram_2)
assert_less_equal(statistic_data.probability, 0.334)
assert_greater_equal(statistic_data.probability, 0.332)
statistic_data = self.provider.datamap_find(arr_3_gram_1)
assert_less_equal(statistic_data.probability, 1.1)
assert_greater_equal(statistic_data.probability, 0.9)
def test_interaction_information(self):
log.info("Statistics> test_interaction_information")
# Add multiple data
for case in self.test_case:
self.provider.add_one_metadata(case)
# Add data's count
arr_2_gram_1 = [self.aaa, self.bbb]
arr_2_gram_2 = [self.aaa, self.ccc]
arr_3_gram_1 = [self.aaa, self.bbb, self.ccc]
self.provider.add_one_rawdata_count(arr_2_gram_1, 2)
self.provider.add_one_rawdata_count(arr_2_gram_2, 1)
self.provider.add_one_rawdata_count(arr_3_gram_1, 1)
# Calculate probabilities
PyProbabilityAtom().calculate_probabilities(self.provider)
PyEntropyAtom().calculate_entropies(self.provider)
PyInteractionInformationAtom().calculate_interaction_informations(self.provider)
statistic_data = self.provider.datamap_find(arr_2_gram_1)
assert_less_equal(statistic_data.interaction_information, -0.388)
assert_greater_equal(statistic_data.interaction_information, -0.390)
statistic_data = self.provider.datamap_find(arr_2_gram_2)
assert_less_equal(statistic_data.interaction_information, -0.527)
assert_greater_equal(statistic_data.interaction_information, -0.529)
statistic_data = self.provider.datamap_find(arr_3_gram_1)
assert_less_equal(statistic_data.interaction_information, -0.917)
assert_greater_equal(statistic_data.interaction_information, -0.919)
def get_weighted_tv(atoms):
if len(atoms) < 1:
log.info("Weighted TruthValue can't be evaluated with small size.")
return TruthValue()
elif len(atoms) == 1:
return atoms[0].tv
mean_sum = 0
weighted_strength_sum = 0
confidence_sum = 0
link_count = 0
for atom in atoms:
weighted_strength_sum += (atom.tv.confidence * atom.tv.mean)
confidence_sum += atom.tv.confidence
link_count += 1
if confidence_sum != 0:
new_strength = weighted_strength_sum / confidence_sum
else:
# This is arithmetic mean, maybe given atoms doesn't have TruthValue.
for atom in atoms:
mean_sum += atom.tv.mean
new_strength = mean_sum / link_count
# TODO: Currently, confidence value for new blended node is just
# average of old value.
new_confidence = confidence_sum / link_count
return TruthValue(new_strength, new_confidence)
def main():
# Init loggers
log.set_level("fine")
log.set_sync(False)
agent_log.set_level("fine")
agent_log.set_sync(False)
ure_logger().set_level("fine")
ure_logger().set_sync(False)
# Set main atomspace
atomspace = AtomSpace()
set_default_atomspace(atomspace)
# Wrap environment
wrapped_env = CartPoleWrapper(env, atomspace)
# Instantiate CartPoleAgent, and tune parameters
cpa = FixedCartPoleAgent(wrapped_env, atomspace)
cpa.delta = 1.0e-16
# Run control loop
while not cpa.control_cycle():
wrapped_env.render()
time.sleep(0.1)
log.info("cycle_count = {}".format(cpa.cycle_count))
log_msg(agent_log, f"The final reward is {cpa.accumulated_reward}.")
def __connect_links_simple(self, decided_atoms, new_blended_atom):
"""
Implementation of simple link connector.
1. Find duplicate, non-duplicate links both.
2. Try to improve some conflict in duplicate links and connect to new
blended atom.
3. Try to connect to new blended atom.
:param list(types.Atom) decided_atoms: List of atoms to search
links to be connected to new blended atom.
:param Atom new_blended_atom: New blended atom.
"""
duplicate_links, non_duplicate_links = \
find_duplicate_links(self.a, decided_atoms)
self.__connect_duplicate_links(duplicate_links, new_blended_atom)
self.__connect_non_duplicate_links(non_duplicate_links)
# Make the links between source nodes and newly blended node.
# TODO: Give proper truth value, not average of truthvalue.
for new_blended_atom in self.ret:
try:
weighted_tv = get_weighted_tv(
self.a.get_incoming(new_blended_atom.h))
except UserWarning as e:
log.info(str(e))
weighted_tv = TruthValue()
for decided_atom in decided_atoms:
self.a.add_link(types.AssociativeLink,
[decided_atom, new_blended_atom], weighted_tv)
def run(self, focus_atoms=None, config_base=None):
"""Execute a conceptual blending algorithm.
Args:
focus_atoms: The atoms to blend.
config_base: A Node to save custom config.
:param focus_atoms: list[Atom]
:param config_base: Atom
Returns:
The blended atom(s).
Example:
[(ConceptNode "car-man"),
(ConceptNode "man-car"),
...]
If a list is empty, then means blender couldn't make a proper
blend atom(s) with given atoms.
:rtype : list[Atom]
"""
try:
self.__prepare(focus_atoms, config_base)
# Choose nodes to blending.
self.chosen_atoms = \
ChooserFinder(self.a).\
get_chooser(self.config_base).\
atom_choose(self.focus_atoms, self.config_base)
# Decide whether or not to execute blending and prepare.
self.decided_atoms = \
DeciderFinder(self.a).\
get_decider(self.config_base).\
blending_decide(self.chosen_atoms, self.config_base)
# Initialize the new blend node.
self.merged_atom = \
MakerFinder(self.a).\
get_maker(self.config_base).\
new_blend_make(self.decided_atoms, self.config_base)
# Make the links between exist nodes and newly blended node.
# Check the severe conflict links in each node and remove.
# Detect and improve conflict links in newly blended node.
self.blended_atoms = \
ConnectorFinder(self.a).\
get_connector(self.config_base).\
link_connect(self.decided_atoms, self.merged_atom, config_base)
# Sum up blending.
self.__clean_up()
except UserWarning as e:
log.info('Skip blending due to: ' + str(e))
self.blended_atoms = []
# Returns the blended atom(s).
return self.blended_atoms
def run(self, focus_atoms=None, config_base=None):
"""Execute a conceptual blending algorithm.
Args:
focus_atoms: The atoms to blend.
config_base: A Node to save custom config.
:param focus_atoms: list[Atom]
:param config_base: Atom
Returns:
The blended atom(s).
Example:
[(ConceptNode "car-man"),
(ConceptNode "man-car"),
...]
If a list is empty, then means blender couldn't make a proper
blend atom(s) with given atoms.
:rtype : list[Atom]
"""
try:
self.__prepare(focus_atoms, config_base)
# Choose nodes to blending.
self.chosen_atoms = \
ChooserFinder(self.a).\
get_chooser(self.config_base).\
atom_choose(self.focus_atoms, self.config_base)
# Decide whether or not to execute blending and prepare.
self.decided_atoms = \
DeciderFinder(self.a).\
get_decider(self.config_base).\
blending_decide(self.chosen_atoms, self.config_base)
# Initialize the new blend node.
self.merged_atom = \
MakerFinder(self.a).\
get_maker(self.config_base).\
new_blend_make(self.decided_atoms, self.config_base)
# Make the links between exist nodes and newly blended node.
# Check the severe conflict links in each node and remove.
# Detect and improve conflict links in newly blended node.
self.blended_atoms = \
ConnectorFinder(self.a).\
get_connector(self.config_base).\
link_connect(self.decided_atoms, self.merged_atom, config_base)
# Sum up blending.
self.__clean_up()
except UserWarning as e:
log.info('Skip blending due to: ' + str(e))
self.blended_atoms = []
# Returns the blended atom(s).
return self.blended_atoms
def __get_max_n_gram(
self,
conflict_link_cases,
non_conflict_link_cases,
non_duplicate_link_cases,
related_node_target_links
):
"""Decide the max value of n_gram, from every category link set.
MAX(
(USER DEFINED LIMIT),
length of (related_node_target_link),
length of (conflict_link + non_conflict_link + non_duplicate_link)
)
Args:
conflict_link_cases: Conflicted link tuples list.
non_conflict_link_cases: Non-conflict links list.
non_duplicate_link_cases: Non-duplicated links list.
related_node_target_links: Target link tuples in related node list.
:param conflict_link_cases: list[list[EqualLinkKey]]
:param non_conflict_link_cases: list[EqualLinkKey]
:param non_duplicate_link_cases: list[EqualLinkKey]
:param related_node_target_links: list[list[EqualLinkKey]]
Returns:
The max value of n_gram.
:rtype : int
"""
conflict_link_n_gram = 0 \
if len(conflict_link_cases) == 0 \
else len(conflict_link_cases[0])
merged_link_n_gram = \
conflict_link_n_gram + \
len(non_conflict_link_cases) + \
len(non_duplicate_link_cases)
target_n_gram = list(map(lambda x: len(x), related_node_target_links))
target_n_gram.append(merged_link_n_gram)
n_gram = self.data_n_gram_limit \
if 0 < self.data_n_gram_limit < max(target_n_gram) \
else max(target_n_gram)
if n_gram == self.data_n_gram_limit:
log.info(
"ConnectConflictInteractionInformation: "
"n_gram was limited to: " + str(self.data_n_gram_limit) +
", original n_gram was: " + str(max(target_n_gram))
)
return n_gram
def get_weighted_tv(atoms):
"""Calculate the weighted average of TruthValue of atoms list.
T1 ... Tk = TruthValue in source atoms
A = new TruthValue
strength of A = sA
confidence of A = cA
sA = revision of T1...Tk = (sT1*cT1 + ... + sTk*cTk) / (cT1 + ... + cTk)
cA = (cT1 + ... + cTk) / k
See: https://groups.google.com/forum/#!topic/opencog/fa5c4yE8YdU
Args:
atoms: A list of atom to calculate the weighted average of TruthValue.
:param atoms: list[Atom]
Returns:
An weighted average of TruthValue.
:rtype: TruthValue
"""
if len(atoms) < 1:
log.info("Weighted TruthValue can't be evaluated with small size.")
return TruthValue()
elif len(atoms) == 1:
return atoms[0].tv
mean_sum = 0
weighted_strength_sum = 0
confidence_sum = 0
link_count = 0
for atom in atoms:
weighted_strength_sum += (atom.tv.confidence * atom.tv.mean)
confidence_sum += atom.tv.confidence
link_count += 1
if confidence_sum != 0:
new_strength = weighted_strength_sum / confidence_sum
else:
# This is arithmetic mean, maybe given atoms doesn't have TruthValue.
for atom in atoms:
mean_sum += atom.tv.mean
new_strength = mean_sum / link_count
# TODO: Currently, confidence value for new blended node is just
# average of old value.
new_confidence = confidence_sum / link_count
return TruthValue(new_strength, new_confidence)
def get_weighted_tv(atoms):
"""Calculate the weighted average of TruthValue of atoms list.
T1 ... Tk = TruthValue in source atoms
A = new TruthValue
strength of A = sA
confidence of A = cA
sA = revision of T1...Tk = (sT1*cT1 + ... + sTk*cTk) / (cT1 + ... + cTk)
cA = (cT1 + ... + cTk) / k
See: https://groups.google.com/forum/#!topic/opencog/fa5c4yE8YdU
Args:
atoms: A list of atom to calculate the weighted average of TruthValue.
:param atoms: list[Atom]
Returns:
An weighted average of TruthValue.
:rtype: TruthValue
"""
if len(atoms) < 1:
log.info("Weighted TruthValue can't be evaluated with small size.")
return TruthValue()
elif len(atoms) == 1:
return atoms[0].tv
mean_sum = 0
weighted_strength_sum = 0
confidence_sum = 0
link_count = 0
for atom in atoms:
weighted_strength_sum += (atom.tv.confidence * atom.tv.mean)
confidence_sum += atom.tv.confidence
link_count += 1
if confidence_sum != 0:
new_strength = weighted_strength_sum / confidence_sum
else:
# This is arithmetic mean, maybe given atoms doesn't have TruthValue.
for atom in atoms:
mean_sum += atom.tv.mean
new_strength = mean_sum / link_count
# TODO: Currently, confidence value for new blended node is just
# average of old value.
new_confidence = confidence_sum / link_count
return TruthValue(new_strength, new_confidence)
def atom_choose(self, focus_atoms, config_base):
self.last_status = self.Status.IN_PROCESS
try:
self.atom_choose_impl(focus_atoms, config_base)
except UserWarning as e:
log.info("Skipping choose, caused by '" + str(e) + "'")
log.info("Last status is '" +
self.Status.reverse_mapping[self.last_status] + "'")
raise e
if self.last_status == self.Status.IN_PROCESS:
self.last_status = self.Status.SUCCESS_CHOOSE
return self.ret
def blending_decide(self, chosen_atoms, config_base):
self.last_status = self.Status.IN_PROCESS
try:
self.blending_decide_impl(chosen_atoms, config_base)
except UserWarning as e:
log.info("Skipping decide, caused by '" + str(e) + "'")
log.info("Last status is '" +
self.Status.reverse_mapping[self.last_status] + "'")
raise e
if self.last_status == self.Status.IN_PROCESS:
self.last_status = self.Status.SUCCESS_DECIDE
return self.ret
def __get_max_n_gram(self, conflict_link_cases, non_conflict_link_cases,
non_duplicate_link_cases, related_node_target_links):
"""Decide the max value of n_gram, from every category link set.
MAX(
(USER DEFINED LIMIT),
length of (related_node_target_link),
length of (conflict_link + non_conflict_link + non_duplicate_link)
)
Args:
conflict_link_cases: Conflicted link tuples list.
non_conflict_link_cases: Non-conflict links list.
non_duplicate_link_cases: Non-duplicated links list.
related_node_target_links: Target link tuples in related node list.
:param conflict_link_cases: list[list[EqualLinkKey]]
:param non_conflict_link_cases: list[EqualLinkKey]
:param non_duplicate_link_cases: list[EqualLinkKey]
:param related_node_target_links: list[list[EqualLinkKey]]
Returns:
The max value of n_gram.
:rtype : int
"""
conflict_link_n_gram = 0 \
if len(conflict_link_cases) == 0 \
else len(conflict_link_cases[0])
merged_link_n_gram = \
conflict_link_n_gram + \
len(non_conflict_link_cases) + \
len(non_duplicate_link_cases)
target_n_gram = list(map(lambda x: len(x), related_node_target_links))
target_n_gram.append(merged_link_n_gram)
n_gram = self.data_n_gram_limit \
if 0 < self.data_n_gram_limit < max(target_n_gram) \
else max(target_n_gram)
if n_gram == self.data_n_gram_limit:
log.info("ConnectConflictInteractionInformation: "
"n_gram was limited to: " + str(self.data_n_gram_limit) +
", original n_gram was: " + str(max(target_n_gram)))
return n_gram
def new_blend_make(self, decided_atoms, config_base):
self.last_status = self.Status.IN_PROCESS
try:
self.new_blend_make_impl(decided_atoms, config_base)
except UserWarning as e:
log.info("Skipping make, caused by '" + str(e) + "'")
log.info(
"Last status is '" +
self.Status.reverse_mapping[self.last_status] +
"'"
)
raise e
if self.last_status == self.Status.IN_PROCESS:
self.last_status = self.Status.SUCCESS_MAKE
return self.ret
def link_connect(self, decided_atoms, new_blended_atom, config_base):
self.last_status = self.Status.IN_PROCESS
try:
self.link_connect_impl(decided_atoms, new_blended_atom, config_base)
except UserWarning as e:
log.info("Skipping connect, caused by '" + str(e) + "'")
log.info(
"Last status is '" +
self.Status.reverse_mapping[self.last_status] +
"'"
)
raise e
if self.last_status == self.Status.IN_PROCESS:
self.last_status = self.Status.SUCCESS_CONNECT
return self.ret
def test_data_provider(self):
log.info("Statistics> test_data_provider")
# Add one data
is_first_insert = self.provider.add_one_metadata(self.aaa)
assert_true(is_first_insert)
# Re-add one data
is_first_insert = self.provider.add_one_metadata(self.aaa)
assert_false(is_first_insert)
# Add multiple data
for case in self.test_case:
self.provider.add_one_metadata(case)
assert_equal(self.provider.dataset_size(), 6)
# Add data's count (n_gram = 2)
arr_2_gram_1 = [self.aaa, self.bbb]
arr_2_gram_2 = [self.aaa, self.ccc]
self.provider.add_one_rawdata_count(arr_2_gram_1, 2)
self.provider.add_one_rawdata_count(arr_2_gram_2, 1)
# Add data's count (n_gram = 3)
arr_3_gram_1 = [self.aaa, self.bbb, self.ccc]
self.provider.add_one_rawdata_count(arr_3_gram_1, 1)
# Test key vector
key_vector_1 = self.provider.make_key_from_data(self.test_case)
assert_equal(len(key_vector_1), 6)
combination_array = [True, False, True, False, True, False]
key_vector_2 = self.provider.make_key_from_data(
self.test_case, combination_array)
assert_equal(len(key_vector_2), 3)
value_vector = self.provider.make_data_from_key(self.a, key_vector_1)
assert_equal(len(value_vector), 6)
def run_message_passing_ure():
fc_message_sending_rule_name = DefinedSchemaNode("fc-message-sending-rule")
DefineLink(fc_message_sending_rule_name, create_messages_rule)
fc_message_sending_rbs = ConceptNode("fc-message-sending-rule")
MemberLink(fc_message_sending_rule_name, fc_message_sending_rbs)
EvaluationLink(PredicateNode("URE:FC:retry-exhausted-sources"),
fc_message_sending_rbs).tv = TruthValue(1, 1)
# Set URE maximum-iterations
from opencog.scheme_wrapper import scheme_eval
execute_code = \
'''
(use-modules (opencog) (opencog rule-engine))
(ure-set-num-parameter (ConceptNode "fc-message-sending-rbs") "URE:maximum-iterations" 10)
'''
scheme_eval(atomspace, execute_code)
log.info("=== Dump AtomSpace Begin ===")
for atom in atomspace:
if not atom.incoming:
log.info(str(atom))
log.info("=== Dump AtomSpace End ===")
chainer = ForwardChainer(
atomspace, ConceptNode("fc-message-sending-rule"),
get_directed_edge(VariableNode("$V1"), VariableNode("$V2")),
VariableList(
TypedVariableLink(VariableNode("$V1"), TypeNode("ConceptNode")),
TypedVariableLink(VariableNode("$V2"), TypeNode("ConceptNode"))))
# chainer = BackwardChainer(atomspace,
# ConceptNode("fc-message-sending-rule"),
# get_message(VariableNode("$V1"), VariableNode("$V2")),
# VariableList(
# TypedVariableLink(VariableNode("$V1"), TypeNode("ConceptNode")),
# TypedVariableLink(VariableNode("$V2"), TypeNode("ConceptNode"))))
chainer.do_chain()
results = chainer.get_results()
# ChaseAgent
ca = ChaseAgent(wrapped_env, action_space, pgoal, ngoal)
# Eat some food.
ca.eat(4)
time.sleep(5)
# Training/learning loop
lt_iterations = 3 # Number of learning-training iterations
lt_period = 200 # Duration of a learning-training iteration
for i in range(lt_iterations):
ca.reset_action_counter()
par = ca.accumulated_reward # Keep track of the reward before
# Discover patterns to make more informed decisions
agent_log.info("Start learning ({}/{})".format(i + 1, lt_iterations))
ca.learn()
ca.wake()
# Run agent to accumulate percepta
agent_log.info("Start training ({}/{})".format(i + 1, lt_iterations))
for j in range(lt_period):
ca.control_cycle()
time.sleep(0.01)
log.info("cycle_count = {}".format(ca.cycle_count))
nar = ca.accumulated_reward - par
agent_log.info("Accumulated reward during {}th iteration = {}".format(
i + 1, nar))
agent_log.info("Action counter during {}th iteration:\n{}".format(
i + 1, ca.action_counter))
ca.eat(8 - i)
# ChaseAgent
ca = ChaseAgent(wrapped_env, action_space, pgoal, ngoal)
# Eat some food.
ca.eat(4)
time.sleep(5)
# Training/learning loop
lt_iterations = 3 # Number of learning-training iterations
lt_period = 200 # Duration of a learning-training iteration
for i in range(lt_iterations):
ca.reset_action_counter()
par = ca.accumulated_reward # Keep track of the reward before
# Discover patterns to make more informed decisions
agent_log.info("Start learning ({}/{})".format(i + 1, lt_iterations))
ca.learn()
ca.wake()
# Run agent to accumulate percepta
agent_log.info("Start training ({}/{})".format(i + 1, lt_iterations))
for j in range(lt_period):
ca.step()
time.sleep(0.01)
log.info("step_count = {}".format(ca.step_count))
nar = ca.accumulated_reward - par
agent_log.info("Accumulated reward during {}th iteration = {}".format(
i + 1, nar))
agent_log.info("Action counter during {}th iteration:\n{}".format(
i + 1, ca.action_counter))
ca.eat(8 - i)
the example simple, the below is static; it simply counts green and
red lights, and halts at the first red light.
The if-then is implemented via a matching clause with the pattern
matcher. When a match is seen, the matcher moves on to the next
clause.
"""
from opencog.atomspace import AtomSpace, TruthValue, types, get_type_name
from opencog.bindlink import satisfaction_link
from opencog.type_constructors import *
from opencog.logger import Logger, log
# Logging will be written to opencog.log in the current directory.
log.set_level('DEBUG')
log.info("Starting the stop-go demo")
# The atomspace where everything will live.
atomspace = AtomSpace()
set_type_ctor_atomspace(atomspace)
# The callback counts the number fo red and green lights.
# It returns a TruthValue of TRUE for green lights and FALSE for the
# red lights. FALSE is interpreted as a mismatch (failure to satisfy)
# by the pattner matcher, and thus, the pattern matcher will backtrack
# and sarch for a different solution. Since the example below contains
# no variables, it will just backtrack to the start, and then report
# non-satisfiability (which is what we want, when we get a red light).
green = 0
red = 0
# https://github.com/noskill/opencog-intro
import os.path
from opencog.scheme_wrapper import scheme_eval, scheme_eval_h
from opencog.atomspace import TruthValue
from opencog.backwardchainer import BackwardChainer
from opencog.type_constructors import *
from opencog.utilities import initialize_opencog
from opencog.logger import Logger, log
# Logging will be written to opencog.log in the current directory.
# log.set_level('FINE')
# log.set_level('DEBUG')
log.set_level('INFO')
log.info("Starting the Socrates sample")
atomspace = AtomSpace()
initialize_opencog(atomspace)
scheme_eval(atomspace, '(use-modules (opencog))')
scheme_eval(atomspace, '(use-modules (opencog exec))')
scheme_eval(atomspace, '(use-modules (opencog query))')
scheme_eval(atomspace, '(use-modules (opencog rule-engine))')
pln_path = os.path.expanduser("/home/opencog/share/opencog/opencog/pln")
pln_config_path = os.path.expanduser(
"/home/opencog/share/opencog/opencog/pln/pln-config.scm")
scheme_eval(atomspace, '(add-to-load-path "{0}")'.format(pln_path))
the example simple, the below is static; it simply counts green and
red lights, and halts at the first red light.
The if-then is implemented via a matching clause with the pattern
matcher. When a match is seen, the matcher moves on to the next
clause.
"""
from opencog.atomspace import AtomSpace, TruthValue, types, get_type_name
from opencog.bindlink import satisfaction_link
from opencog.type_constructors import *
from opencog.logger import Logger, log
# Logging will be written to opencog.log in the current directory.
log.set_level('DEBUG')
log.info("Starting the stop-go demo")
# The atomspace where everything will live.
atomspace = AtomSpace()
set_type_ctor_atomspace(atomspace)
# The callback counts the number fo red and green lights.
# It returns a TruthValue of TRUE for green lights and FALSE for the
# red lights. FALSE is interpreted as a mismatch (failure to satisfy)
# by the pattner matcher, and thus, the pattern matcher will backtrack
# and sarch for a different solution. Since the example below contains
# no variables, it will just backtrack to the start, and then report
# non-satisfiability (which is what we want, when we get a red light).
green = 0
red = 0
def print_detail(self, provider):
log.info(provider.print_data_map())
