156 lines
5.7 KiB
Python
156 lines
5.7 KiB
Python
from agentState import AgentState
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from typing import Dict, Tuple
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from city import City
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from gridCellType import GridCellType
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from agentActionType import AgentActionType
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from agentOrientation import AgentOrientation
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from queue import Queue, PriorityQueue
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from turnCar import turn_left_orientation, turn_right_orientation
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class Succ:
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state: AgentState
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action: AgentActionType
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cost: int
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predicted_cost: int
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def __init__(self, state: AgentState, action: AgentActionType, cost: int, predicted_cost: int) -> None:
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self.state = state
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self.action = action
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self.cost = cost
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self.predicted_cost = cost
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class SuccList:
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succ_list: list[Succ]
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def __init__(self, succ_list: list[Succ]) -> None:
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self.succ_list = succ_list
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def __lt__(self, other):
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return self.succ_list[-1].predicted_cost < other.succ_list[-1].predicted_cost
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def __gt__(self, other):
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return self.succ_list[-1].predicted_cost > other.succ_list[-1].predicted_cost
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def find_path_to_nearest_can(startState: AgentState, grid: Dict[Tuple[int, int], GridCellType], city: City) -> list[
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AgentActionType]:
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q: PriorityQueue[SuccList] = PriorityQueue()
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visited: list[AgentState] = []
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startStates: SuccList = SuccList(
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[Succ(startState, AgentActionType.UNKNOWN, 0, _heuristics(startState.position, city))])
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q.put(startStates)
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while not q.empty():
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currently_checked = q.get()
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visited.append(currently_checked.succ_list[-1].state)
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if is_state_success(currently_checked.succ_list[-1].state, grid):
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return extract_actions(currently_checked)
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successors = succ(currently_checked.succ_list[-1], grid, city)
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for s in successors:
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already_visited = False
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for v in visited:
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if v.position[0] == s.state.position[0] and v.position[1] == s.state.position[
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1] and s.state.orientation == v.orientation:
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already_visited = True
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break
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if already_visited:
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continue
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if is_state_valid(s.state, grid):
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new_list = currently_checked.succ_list.copy()
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new_list.append(s)
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q.put(SuccList(new_list))
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return []
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def extract_actions(successors: SuccList) -> list[AgentActionType]:
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output: list[AgentActionType] = []
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for s in successors.succ_list:
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if s.action != AgentActionType.UNKNOWN:
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output.append(s.action)
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return output
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def succ(succ: Succ, grid: Dict[Tuple[int, int], GridCellType], city: City) -> list[Succ]:
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result: list[Succ] = []
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turn_left_cost = 1 + succ.cost
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result.append(
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Succ(AgentState(succ.state.position, turn_left_orientation(succ.state.orientation)), AgentActionType.TURN_LEFT,
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turn_left_cost, turn_left_cost + _heuristics(succ.state.position, city)))
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turn_right_cost = 1 + succ.cost
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result.append(Succ(AgentState(succ.state.position, turn_right_orientation(succ.state.orientation)),
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AgentActionType.TURN_RIGHT, turn_right_cost,
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turn_right_cost + _heuristics(succ.state.position, city)))
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state_succ = move_forward_succ(succ, city, grid)
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if state_succ != None:
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result.append(state_succ)
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return result
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def move_forward_succ(succ: Succ, city: City, grid: Dict[Tuple[int, int], GridCellType]) -> Succ:
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position = get_next_cell(succ.state)
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if position == None:
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return None
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cost = get_cost_for_action(AgentActionType.MOVE_FORWARD, grid[position]) + succ.cost
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return Succ(AgentState(position, succ.state.orientation), AgentActionType.MOVE_FORWARD, cost,
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cost + _heuristics(position, city))
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def get_next_cell(state: AgentState) -> Tuple[int, int]:
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if state.orientation == AgentOrientation.UP:
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if state.position[1] - 1 < 1:
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return None
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return (state.position[0], state.position[1] - 1)
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if state.orientation == AgentOrientation.DOWN:
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if state.position[1] + 1 > 27:
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return None
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return (state.position[0], state.position[1] + 1)
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if state.orientation == AgentOrientation.LEFT:
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if state.position[0] - 1 < 1:
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return None
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return (state.position[0] - 1, state.position[1])
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if state.position[0] + 1 > 27:
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return None
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return (state.position[0] + 1, state.position[1])
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def is_state_success(state: AgentState, grid: Dict[Tuple[int, int], GridCellType]) -> bool:
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next_cell = get_next_cell(state)
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try:
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return grid[next_cell] == GridCellType.GARBAGE_CAN
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except:
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return False
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def get_cost_for_action(action: AgentActionType, cell_type: GridCellType) -> int:
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if action == AgentActionType.TURN_LEFT or action == AgentActionType.TURN_RIGHT:
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return 1
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if cell_type == GridCellType.SPEED_BUMP:
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if action == AgentActionType.MOVE_FORWARD:
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return 10
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if action == AgentActionType.MOVE_FORWARD:
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return 3
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def is_state_valid(state: AgentState, grid: Dict[Tuple[int, int], GridCellType]) -> bool:
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try:
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return grid[state.position] == GridCellType.STREET_HORIZONTAL or grid[
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state.position] == GridCellType.STREET_VERTICAL or grid[state.position] == GridCellType.SPEED_BUMP
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except:
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return False
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def _heuristics(position: Tuple[int, int], city: City):
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min_distance: int = 300
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found_nonvisited: bool = False
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for can in city.cans:
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if can.is_visited:
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continue
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found_nonvisited = True
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distance = 3 * (abs(position[0] - can.position[0]) + abs(position[1] - can.position[1]))
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if distance < min_distance:
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min_distance = distance
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if found_nonvisited:
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return min_distance
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return -1 |