some fixes, big work on devsociety and get_best_

This commit is contained in:
Thefeli73 2020-10-07 04:04:39 +02:00
parent cf977331e3
commit cc693ee83d

60
main.py
View File

@ -5,15 +5,18 @@ from sys import exit
from game_layer import GameLayer
import game_state
import traceback
import random
api_key = "74e3998d-ed3d-4d46-9ea8-6aab2efd8ae3"
# The different map names can be found on considition.com/rules
map_name = "training1" # TODO: You map choice here. If left empty, the map "training1" will be selected.
game_layer = GameLayer(api_key)
# settings
use_regulator = False
other_upgrade_threshold = 0.25
time_until_run_ends = 70
utilities = 3
money_reserve_multiplier = 1.5
money_reserve_multiplier = 1
def main():
@ -73,22 +76,35 @@ def take_turn():
def develop_society():
global state, queue_timeout, available_tiles, utilities
global state, queue_timeout, available_tiles, utilities, money_reserve_multiplier
queue_reset = 10
if queue_timeout > 1:
queue_timeout -= 1
best_residence = calculate_best_residence()
best_upgrade = get_best_upgrade()
build_residence_score = 0
build_upgrade_score = 0
# priority scores, 1 = very urgent, 0 = not urgent at all
# queue modifier * funds modifier * existing houses modifier
build_residence_score = (state.housing_queue / (15 * queue_timeout)) * (1 - (7500 / (1 + state.funds))) * (1 - (len(state.residences) / (1 + len(available_tiles) - utilities)))
# build_residence_score = (state.housing_queue / (15 * queue_timeout)) * (state.funds/(money_reserve_multiplier * 18000)) * (1 - (len(state.residences) / (1 + len(available_tiles) - utilities)))
if len(state.residences) < 1:
build_residence_score = 100
elif state.housing_queue < 5:
build_residence_score = 0
elif best_residence:
build_residence_score = best_residence[0] # * (state.housing_queue / (15 * queue_timeout))
elif state.housing_queue > 15 and queue_timeout <= 0:
build_residence_score = 100
#
upgrade_residence_score = 0
# existing houses modifier * funds modifier * existing utilities modifier
build_utility_score = (len(state.residences) / (1 + len(available_tiles)-utilities)) * (1 - (16000 / (1 + state.funds))) * (1 - (len(state.utilities) / utilities))
# turn modifier * funds modifier
build_upgrade_score = (1 - (state.turn / 700)) * (2 - (15000 / (1 + state.funds)))
# build_upgrade_score = (1 - (state.turn / 700)) * (state.funds/(money_reserve_multiplier * 7200))
if best_upgrade:
build_upgrade_score = best_upgrade[0]
if len(state.residences) < 1:
build_residence_score = 100
decision = [
('build_residence', build_residence_score),
@ -99,35 +115,29 @@ def develop_society():
def sort_key(e):
return e[1]
decision.sort(reverse=True, key=sort_key)
for i in range(4):
print(decision)
if decision[0][1] >= 0:
if decision[0][0] == "build_residence": # build housing
queue_timeout = 5
#if len(state.residences) < len(state.available_residence_buildings):
# return build(state.available_residence_buildings[len(state.residences)].building_name)
#else:
cbr = calculate_best_residence()
if cbr:
return build(cbr[1])
queue_timeout = queue_reset
if best_residence:
return build(best_residence[1])
if decision[0][0] == "build_utility": # build utilities
#return build("WindTurbine")
pass
if decision[0][0] == "upgrade_residence": # build utilities
if decision[0][0] == "upgrade_residence": # upgrade housing
pass
if decision[0][0] == "build_upgrade": # build upgrades
if random.random() < other_upgrade_threshold:
for residence in state.residences:
if state.available_upgrades[0].name not in residence.effects and (money_reserve_multiplier*3500 < state.funds) and ((total_income() - 6) > 50):
game_layer.buy_upgrade((residence.X, residence.Y), state.available_upgrades[0].name)
return True
if state.available_upgrades[5].name not in residence.effects and (money_reserve_multiplier*1250 < state.funds):
if use_regulator and state.available_upgrades[5].name not in residence.effects and (money_reserve_multiplier*1250 < state.funds):
game_layer.buy_upgrade((residence.X, residence.Y), state.available_upgrades[5].name)
return True
gbp = get_best_upgrade()
if gbp:
game_layer.buy_upgrade((gbp[2].X, gbp[2].Y), gbp[1])
if best_upgrade:
game_layer.buy_upgrade((best_upgrade[2].X, best_upgrade[2].Y), best_upgrade[1])
return True
del decision[0]
return False
@ -218,7 +228,7 @@ def calculate_best_upgrade(current_building):
upgrade_co2 = (effect.co2_per_pop_increase * 0.03) * current_pop * rounds_left + (0.1 * lifetime_energy / 1000)
old_co2 = 0.03 * current_pop * rounds_left + (0.1 * old_lifetime_energy / 1000)
co2 = upgrade_co2 - old_co2
max_happiness = effect.max_happiness_increase * rounds_left
max_happiness = effect.max_happiness_increase * current_pop * rounds_left
score = max_happiness/10 - co2
best_upgrade.append((score, upgrade.name))
@ -243,7 +253,7 @@ def calculate_best_residence():
lifetime_energy = (residence_blueprint.base_energy_need + average_heating_energy) * rounds_left
co2 = 0.03 * residence_blueprint.max_pop * rounds_left + residence_blueprint.co2_cost + (0.1 * lifetime_energy / 1000)
max_happiness = residence_blueprint.max_happiness * rounds_left
max_happiness = residence_blueprint.max_happiness * residence_blueprint.max_pop * rounds_left
score = residence_blueprint.max_pop*15 + max_happiness/10 - co2
best_residence.append((score, residence_blueprint.building_name))