Considition-2020/main.py

# import api
import time
import sys
from sys import exit
from game_layer import GameLayer
import game_state
import traceback

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)
state = game_layer.game_state
usePrebuiltStrategy = False
timeUntilRunEnds = 70
utilities = 3

building_under_construction = False
availableTiles = []


def main():
    #game_layer.force_end_game()
    game_layer.new_game(map_name)
    print("Starting game: " + game_layer.game_state.game_id)
    game_layer.start_game()
    # exit game after timeout
    start_time = time.time()
    chartMap()
    while game_layer.game_state.turn < game_layer.game_state.max_turns:
        try:
            take_turn()
        except Exception:
            print(traceback.format_exc())
            game_layer.end_game()
            exit()
        time_diff = time.time() - start_time
        if time_diff > timeUntilRunEnds:
            game_layer.end_game()
            exit()
    print("Done with game: " + game_layer.game_state.game_id)
    print("Final score was: " + str(game_layer.get_score()["finalScore"]))

def linus_take_turn():
    freeSpace = []

    state = game_layer.game_state
    for i in range(len(state.map)-1):
        for j in range(len(state.map)-1):
            if state.map[i][j] == 0:
                freeSpace.append((i,j))

    #print(mylist)

    if (game_layer.game_state.turn == 0):
        game_layer.place_foundation(freeSpace[2], game_layer.game_state.available_residence_buildings[0].building_name)
    the_first_residence = state.residences[0]
    if the_first_residence.build_progress < 100:
        game_layer.build(freeSpace[2])
    if len(state.residences)==1:
        game_layer.place_foundation(freeSpace[3], game_layer.game_state.available_residence_buildings[4].building_name)
    the_second_residence = state.residences[1]
    if the_second_residence.build_progress < 100:
        game_layer.build(freeSpace[3])
    elif the_first_residence.health < 70:
        game_layer.maintenance(freeSpace[2])
    elif the_second_residence.health < 70:
        game_layer.maintenance(freeSpace[3])
    elif (the_second_residence.health > 70) and not len(state.utilities) > 0:
        game_layer.place_foundation(freeSpace[4], game_layer.game_state.available_utility_buildings[2].building_name)
    elif (state.utilities[0].build_progress < 100):
        game_layer.build(freeSpace[4])

    else:
    # messages and errors for console log
        game_layer.wait()
    for message in game_layer.game_state.messages:
        print(message)
    for error in game_layer.game_state.errors:
        print("Error: " + error)

def take_turn():
    if not usePrebuiltStrategy:
        # TODO Implement your artificial intelligence here.
        # TODO Take one action per turn until the game ends.
        # TODO The following is a short example of how to use the StarterKit
        if something_needs_attention():
            pass
        else:
            develop_society()
        # messages and errors for console log
        for message in game_layer.game_state.messages:
            print(message)
        for error in game_layer.game_state.errors:
            print("Error: " + error)


    # pre-made test strategy
    # which came with
    # starter kit
    if usePrebuiltStrategy:
        state = game_layer.game_state
        if len(state.residences) < 1:
            for i in range(len(state.map)):
                for j in range(len(state.map)):
                    if state.map[i][j] == 0:
                        x = i
                        y = j
                        break
            game_layer.place_foundation((x, y), game_layer.game_state.available_residence_buildings[0].building_name)
        else:
            the_only_residence = state.residences[0]
            if the_only_residence.build_progress < 100:
                game_layer.build((the_only_residence.X, the_only_residence.Y))
            elif the_only_residence.health < 50:
                game_layer.maintenance((the_only_residence.X, the_only_residence.Y))
            elif the_only_residence.temperature < 18:
                blueprint = game_layer.get_residence_blueprint(the_only_residence.building_name)
                energy = blueprint.base_energy_need + 0.5 \
                         + (the_only_residence.temperature - state.current_temp) * blueprint.emissivity / 1 \
                         - the_only_residence.current_pop * 0.04
                game_layer.adjust_energy_level((the_only_residence.X, the_only_residence.Y), energy)
            elif the_only_residence.temperature > 24:
                blueprint = game_layer.get_residence_blueprint(the_only_residence.building_name)
                energy = blueprint.base_energy_need - 0.5 \
                         + (the_only_residence.temperature - state.current_temp) * blueprint.emissivity / 1 \
                         - the_only_residence.current_pop * 0.04
                game_layer.adjust_energy_level((the_only_residence.X, the_only_residence.Y), energy)
            elif state.available_upgrades[0].name not in the_only_residence.effects:
                game_layer.buy_upgrade((the_only_residence.X, the_only_residence.Y), state.available_upgrades[0].name)
            else:
                game_layer.wait()
        for message in game_layer.game_state.messages:
            print(message)
        for error in game_layer.game_state.errors:
            print("Error: " + error)


def chartMap():
    state = game_layer.game_state
    for x in range(len(state.map) - 1):
        for y in range(len(state.map) - 1):
            if state.map[x][y] == 0:
                availableTiles.append((x, y))
    optimizeAvailableTiles()

def optimizeAvailableTiles():
    #hitta #utilities antal bästa platser i mitten av smeten och sätt de först, sätt allt runt dem i ordning så närmast är längst fram i listan
    pass


def adjustEnergy(current_building, target_temp):
    current_blueprint = game_layer.get_residence_blueprint(current_building.building_name)

    base_energy_need = current_blueprint.base_energy_need
    indoor_temp = current_building.temperature
    degrees_per_pop = 0.04
    current_pop = current_building.current_pop
    outdoor_temp = game_layer.game_state.current_temp
    emissivity = current_blueprint.emissivity
    degrees_per_excess_mwh = 0.75

    effective_energy_in = -1 * (base_energy_need + (indoor_temp + degrees_per_pop * current_pop - (indoor_temp - outdoor_temp) * emissivity - target_temp)/degrees_per_excess_mwh)
    game_layer.adjust_energy_level((current_building.X, current_building.Y), effective_energy_in)

def something_needs_attention():
    pass

def develop_society():
    pass

if __name__ == "__main__":
    main()