def comparison_simulations_passAnyDeltaAndPayoffMatrix_simulationsMatchCalculations():
"""This tests that the results returned by the simulations match the results of the calculations."""
# Construct the payoff matrix
payoff_matrix = PrisonersDilemmaPayoff()
for combo in strategy_combinations:
# Pull out each strategy
strategy_one = combo[0]
strategy_two = combo[1]
# Get the result from the calcs
calculation_result, _ = calculate_payoff(strategy_one, strategy_two, payoff_matrix, DELTA, EPSILON)
# Get the result from the sims
simulation_result, _ = simulate_payoff(strategy_one, strategy_two, payoff_matrix, DELTA, trials = 1000)
# Compare them
if abs(simulation_result) > TOLERANCE:
diff = abs(simulation_result - calculation_result) / abs(calculation_result)
if diff <= TOLERANCE:
report_success()
else:
report_failure(combo, payoff_matrix, DELTA, diff)
else:
diff = abs(simulation_result - calculation_result)
if diff <= TOLERANCE:
report_success()
else:
report_failure(combo, payoff_matrix, DELTA, diff)
def calculate_normalised_payoff(self, payoff_matrix, continuation_probability, epsilon):
"""
Compute the normalised payoff of each strategy using an iterated sum that stops at some epsilon
Args:
As per calculations.calculate_normalised_payoff
Returns;
As per calculations.calculate_normalised_payoff
"""
return calculate_payoff(self.strategy_one, self.strategy_two, payoff_matrix,
continuation_probability, epsilon)
def test_calculations_singleResultCombosGiven_ExpectedResultReturned(payoff_values, delta, combo):
"""Test that the normalised payoff for combinations of strategies with memory <= 1 matches the expected result."""
# Construct the payoff matrix
payoff_matrix = PrisonersDilemmaPayoff(P=payoff_values[0], R=payoff_values[1],
S=payoff_values[2], T=payoff_values[3])
strategy_combo = combo[0]
first_strategy = strategy_combo[0]
second_strategy = strategy_combo[1]
# Get the expected result
expected_result = combo[1](payoff_matrix, delta)
# Compute the result (throw away the result for the other strategy)
actual_result, _ = calculate_payoff(first_strategy, second_strategy, payoff_matrix, delta, EPSILON)
# See if they match, within a percentage of tolerance. If the expected result is very small just use the
# difference itself
if abs(expected_result) > TOLERANCE:
assert abs(expected_result - actual_result) / abs(expected_result) <= TOLERANCE
else:
assert abs(expected_result - actual_result) <= TOLERANCE