class Agent(base_agent.BaseAgent):
def __init__(self):
super().__init__()
self.actuator = Actuator()
def reset(self):
super().reset()
self.actuator.reset()
def step(self, obs):
super().step(obs)
features, _ = state_modifier.modified_state_space(obs)
selected = features[0]
friendly_unit_density = features[2]
enemy_unit_density = features[4]
if np.all(friendly_unit_density == 0):
return self.actuator.compute_action(Action.NO_OP, selected,
friendly_unit_density,
enemy_unit_density)
if not self.actuator.units_selected or np.all(selected == 0):
return self.actuator.compute_action(Action.SELECT, selected,
friendly_unit_density,
enemy_unit_density)
else:
return self.actuator.compute_action(Action.ATTACK, selected,
friendly_unit_density,
enemy_unit_density)
def __init__(self):
super(terran_agent, self).__init__()
self.attack_coordinates = None
self.iteration = 0
self.actuator = Actuator()
self.PPO = PPOAgent()
def __init__(self,
state_modifier_func,
map_name_="DefeatRoaches",
render=False,
step_multiplier=None):
'''
Initializes internal pysc2 environment
:param render: Whether to render the game
:param step_multiplier: Step multiplier for pysc2 environment
'''
import sys
from absl import flags
FLAGS = flags.FLAGS
FLAGS(sys.argv)
self.map = map_name_
self.state_modifier_func = state_modifier_func
self._env = sc2_env.SC2Env(
map_name=map_name_,
agent_interface_format=features.AgentInterfaceFormat(
feature_dimensions=features.Dimensions(screen=84, minimap=84),
use_feature_units=True),
step_mul=step_multiplier,
visualize=render,
game_steps_per_episode=None)
self._actuator = Actuator()
self._prev_frame = None
self._curr_frame = None
self._terminal = True
FACTOR = 9 # TODO
self.observation_space = [84, 84, FACTOR]
self.select_space = Actuator._SELECT_SPACE
self.action_space = Actuator._ACTION_SPACE
class MinigameEnvironment:
screen_width = 84
action_width = 64
def __init__(self,
state_modifier_func,
map_name_="DefeatRoaches",
render=False,
step_multiplier=None):
'''
Initializes internal pysc2 environment
:param render: Whether to render the game
:param step_multiplier: Step multiplier for pysc2 environment
'''
import sys
from absl import flags
FLAGS = flags.FLAGS
FLAGS(sys.argv)
self.map = map_name_
self.state_modifier_func = state_modifier_func
self._env = sc2_env.SC2Env(
map_name=map_name_,
agent_interface_format=features.AgentInterfaceFormat(
feature_dimensions=features.Dimensions(screen=84, minimap=84),
use_feature_units=True),
step_mul=step_multiplier,
visualize=render,
game_steps_per_episode=None)
self._actuator = Actuator()
self._prev_frame = None
self._curr_frame = None
self._terminal = True
FACTOR = 9 # TODO
self.observation_space = [84, 84, FACTOR]
self.select_space = Actuator._SELECT_SPACE
self.action_space = Actuator._ACTION_SPACE
def reset(self):
'''
Resets the environment for a new episode
:returns: Observations, reward, terminal, None for start state
'''
self._actuator.reset()
self._terminal = False
self._run_to_next()
self._terminal = self._curr_frame.last()
#agent_obs = self._combine_frames()
agent_obs = self.state_modifier_func(self._curr_frame)
size = len(agent_obs)
if (size == 4):
info = agent_obs[-1]
agent_obs = agent_obs[:-1]
else:
info = None
return agent_obs, self._curr_frame.reward, self._curr_frame.last(
), info # exclude selected
def step(self, action, topleft=None, botright=None):
'''
Runs the environment until the next agent action is required
:param action: 0 for Action.RETREAT or 1 for Action.ATTACK
:returns: Observations, reward, terminal, None
'''
assert not self._terminal, 'Environment must be reset after init or terminal'
assert action in range(5), 'Agent action must be 0-10'
if action == 0:
step_act = Action.SELECT.value
elif action == 1:
step_act = Action.ATTACK.value
elif action == 2:
step_act = Action.MOVE.value
elif action == 3:
step_act = Action.STOP.value
elif action == 4:
step_act = Action.NO_OP.value
else:
step_act = 0
topleft = self.convert_spatial(topleft)
botright = self.convert_spatial(botright)
self._run_to_next(step_act, topleft=topleft, botright=botright)
self._terminal = self._curr_frame.last()
#agent_obs = self._combine_frames()
agent_obs = self.state_modifier_func(self._curr_frame)
if (len(agent_obs) == 4):
info = agent_obs[-1]
agent_obs = agent_obs[:-1]
else:
info = None
return agent_obs, self._curr_frame.reward, self._curr_frame.last(
), info # exclude selected
def _run_to_next(self, start_action=None, topleft=None, botright=None):
if start_action is None:
self._reset_env()
start_action = Action.SELECT.value
if self._curr_frame.last():
return
raw_action = self._actuator.compute_action(start_action,
self._curr_frame,
topleft=topleft,
botright=botright)
self._step_env(raw_action)
"""
# Select action
if (topleft is not None):
#print("Selecting")
friendly_unit_density = custom_obs[2]
assert not np.all(friendly_unit_density == 0), 'All marines dead but not terminal state'
selected = custom_obs[0]
#while not self._actuator.units_selected or np.all(selected == 0):
raw_action = self._actuator.compute_action(Action.SELECT, custom_obs, self._curr_frame, topleft=topleft, botright=botright)
self._step_env(raw_action)
if self._curr_frame.last():
return
custom_obs = self.state_modifier_func(self._curr_frame)
selected = custom_obs[0]
#assert self._actuator.units_selected and np.any(selected > 0), 'Units not selected after select action'
"""
"""
# Move action
if (start_action is not None):
#print("Moving")
last_obs = self.state_modifier_func(self._curr_frame)
raw_action = self._actuator.compute_action(start_action, last_obs, self._curr_frame, topleft=topleft, botright=botright)
self._step_env(raw_action)
"""
def _combine_frames(self):
'''
Combines the previous and current frame for observations
'''
assert self._prev_frame is not None and self._curr_frame is not None, 'Returning to agent after less than 2 frames should be impossible'
custom_prev = self.state_modifier_func(self._prev_frame)[1:]
custom_curr = self.state_modifier_func(self._curr_frame)
# move selected frame to end
custom_curr = custom_curr[np.r_[1:len(custom_curr), 0]]
custom_frames = np.append(custom_prev, custom_curr, axis=0)
return custom_frames
def _reset_env(self):
self._prev_frame = self._curr_frame
self._curr_frame = self._env.reset()[0] # get obs for 1st agent
def _step_env(self, raw_action):
self._prev_frame = self._curr_frame
try:
self._curr_frame = self._env.step([raw_action
])[0] # get obs for 1st agent
except protocol.ConnectionError:
self._curr_frame = self._env.reset()[0]
def convert_spatial(self, coords):
if (coords is None):
return None
new_coords = []
for i in coords:
new_coords.append((i / MinigameEnvironment.action_width) *
MinigameEnvironment.screen_width)
return new_coords
class Agent(base_agent.BaseAgent):
def __init__(self):
super().__init__()
self.actuator = Actuator()
self.reset()
def reset(self):
super().reset()
self.actuator.reset()
self._select_next = True
def step(self, obs):
super().step(obs)
features = self._modified_state_space(obs)
selected = features[0]
friendly_unit_density = features[2]
enemy_unit_density = features[4]
if np.all(friendly_unit_density == 0):
return 4,
if self._select_next or np.all(selected == 0):
self._select_next = False
return 0,
else:
self._select_next = True
target = self._compute_attack_closest(selected, enemy_unit_density)
return 1, target
@staticmethod
def _modified_state_space(obs):
_PLAYER_FRIENDLY = 1
_PLAYER_HOSTILE = 4
def zero_one_norm(array):
arr_max = np.max(array)
arr_min = np.min(array)
denom = arr_max - arr_min
if (denom == 0):
return array
return (array - arr_min) / denom
scr = obs.observation.feature_screen
# Computes array of locations of selected marines
friendly_selected = np.array(scr.selected)
# Computes arrays of locations of marines and enemy units
player_relative = np.array(scr.player_relative)
player_friendly = (player_relative == _PLAYER_FRIENDLY).astype(int)
player_hostile = (player_relative == _PLAYER_HOSTILE).astype(int)
# Computes arrays of hitpoints for marines and enemy units
player_hitpoints = np.array(scr.unit_hit_points)
friendly_hitpoints = np.multiply(player_hitpoints, player_friendly)
hostile_hitpoints = np.multiply(player_hitpoints, player_hostile)
# Computes arrays of density for marines and enemy units
unit_density = np.array(scr.unit_density)
friendly_density = np.multiply(unit_density, player_friendly)
hostile_density = np.multiply(unit_density, player_hostile)
# Normalize friendly_hitpoints and hostile_hitpoints to between 0 and 1
friendly_hitpoints = zero_one_norm(friendly_hitpoints)
hostile_hitpoints = zero_one_norm(hostile_hitpoints)
# Stacks the previous arrays in the order given in the documentation. This will be the primary input to the neural network.
array = np.stack([friendly_selected, friendly_hitpoints,
friendly_density, hostile_hitpoints, hostile_density], axis=0)
return array
@staticmethod
def _compute_attack_closest(selected, enemy_unit_density):
friendly_com = np.expand_dims(
np.array(ndimage.measurements.center_of_mass(selected)), axis=0)
enemy_positions = np.transpose(enemy_unit_density.nonzero())
distances = distance.cdist(friendly_com, enemy_positions)
closest = np.flip(enemy_positions[np.argmin(distances)], 0)
return closest
def __init__(self):
super().__init__()
self.actuator = Actuator()
self.reset()