Задание 2

2026-05-25 10:14:49 +03:00
4 changed files with 460 additions and 0 deletions
--- a/starikovta/docs/task2/report.md
+++ b/starikovta/docs/task2/report.md
--- a/starikovta/maze.txt
+++ b/starikovta/maze.txt
@ -0,0 +1,12 @@
 ###########
 S        #
 # ####### #
 # #     # #
 # # ### # #
 # #   # # #
 # ### # # #
 #     #   #
 ####### # #
 #         E
 ###########
--- a/starikovta/maze_results.csv
+++ b/starikovta/maze_results.csv
@ -0,0 +1,4 @@
 Стратегия,Время(мс),Посещено клеток,Длина пути,Путь найден
 BFS,0.16149994917213917,31,31,True
 DFS,0.17100002150982618,31,31,True
 A*,0.3127999370917678,31,31,True
--- a/starikovta/maze_solver.py
+++ b/starikovta/maze_solver.py
@ -0,0 +1,444 @@
 import time
 import csv
 import os
 from collections import deque
 import heapq
 from abc import ABC, abstractmethod
 # ========== ЭТАП 1: МОДЕЛЬ ЛАБИРИНТА ==========
 class Cell:
    """Клетка лабиринта"""
    def __init__(self, x, y, is_wall=False, is_start=False, is_exit=False):
        self.x = x
        self.y = y
        self.is_wall = is_wall
        self.is_start = is_start
        self.is_exit = is_exit
    def is_passable(self):
        return not self.is_wall
 class Maze:
    """Лабиринт: сетка клеток + старт + выход"""
    def __init__(self, width, height):
        self.width = width
        self.height = height
        self.grid = [[Cell(x, y) for x in range(width)] for y in range(height)]
        self.start = None
        self.exit = None
    def get_cell(self, x, y):
        if 0 <= x < self.width and 0 <= y < self.height:
            return self.grid[y][x]
        return None
    def get_neighbors(self, cell):
        """Возвращает список проходимых соседей (вверх, вниз, влево, вправо)"""
        neighbors = []
        directions = [(0, -1), (0, 1), (-1, 0), (1, 0)]  # вверх, вниз, влево, вправо
        for dx, dy in directions:
            nx, ny = cell.x + dx, cell.y + dy
            neighbor = self.get_cell(nx, ny)
            if neighbor and neighbor.is_passable():
                neighbors.append(neighbor)
        return neighbors
    def set_cell(self, x, y, cell):
        if 0 <= x < self.width and 0 <= y < self.height:
            self.grid[y][x] = cell
 # ========== ЭТАП 2: ПАТТЕРН BUILDER ==========
 class MazeBuilder(ABC):
    """Интерфейс строителя лабиринта"""
    @abstractmethod
    def build_from_file(self, filename):
        pass
 class TextFileMazeBuilder(MazeBuilder):
    """Загружает лабиринт из текстового файла"""
    def build_from_file(self, filename):
        with open(filename, 'r', encoding='utf-8') as f:
            lines = f.readlines()
        # Убираем лишние пробелы и переносы строк
        lines = [line.rstrip('\n\r') for line in lines]
        height = len(lines)
        width = len(lines[0]) if height > 0 else 0
        maze = Maze(width, height)
        start = None
        exit_cell = None
        for y, line in enumerate(lines):
            for x, ch in enumerate(line):
                if ch == '#':
                    cell = Cell(x, y, is_wall=True)
                elif ch == 'S':
                    cell = Cell(x, y, is_start=True)
                    start = cell
                elif ch == 'E':
                    cell = Cell(x, y, is_exit=True)
                    exit_cell = cell
                else:  # пробел или '.' — проход
                    cell = Cell(x, y, is_wall=False)
                maze.set_cell(x, y, cell)
        maze.start = start
        maze.exit = exit_cell
        # Валидация: проверяем, что есть и старт, и выход
        if maze.start is None or maze.exit is None:
            raise ValueError("В лабиринте должны быть S (старт) и E (выход)")
        return maze
 # ========== ЭТАП 3: ПАТТЕРН STRATEGY ==========
 class PathFindingStrategy(ABC):
    """Интерфейс стратегии поиска пути"""
    @abstractmethod
    def find_path(self, maze, start, exit_cell):
        pass
 def reconstruct_path(parents, start, exit_cell):
    """Восстанавливает путь от выхода до старта"""
    path = []
    current = exit_cell
    while current != start:
        path.append(current)
        current = parents.get((current.x, current.y))
        if current is None:
            return []
    path.append(start)
    path.reverse()
    return path
 class BFSStrategy(PathFindingStrategy):
    """Поиск в ширину (гарантирует кратчайший путь)"""
    def find_path(self, maze, start, exit_cell):
        queue = deque()
        queue.append(start)
        visited = {(start.x, start.y)}
        parents = {}
        while queue:
            current = queue.popleft()
            if current == exit_cell:
                return reconstruct_path(parents, start, exit_cell)
            for neighbor in maze.get_neighbors(current):
                if (neighbor.x, neighbor.y) not in visited:
                    visited.add((neighbor.x, neighbor.y))
                    parents[(neighbor.x, neighbor.y)] = current
                    queue.append(neighbor)
        return []  # Путь не найден
 class DFSStrategy(PathFindingStrategy):
    """Поиск в глубину (быстрый, но не гарантирует кратчайший путь)"""
    def find_path(self, maze, start, exit_cell):
        stack = [start]
        visited = {(start.x, start.y)}
        parents = {}
        while stack:
            current = stack.pop()
            if current == exit_cell:
                return reconstruct_path(parents, start, exit_cell)
            for neighbor in maze.get_neighbors(current):
                if (neighbor.x, neighbor.y) not in visited:
                    visited.add((neighbor.x, neighbor.y))
                    parents[(neighbor.x, neighbor.y)] = current
                    stack.append(neighbor)
        return []
 class AStarStrategy(PathFindingStrategy):
    """A* с манхэттенской эвристикой"""
    def _heuristic(self, cell, exit_cell):
        """Манхэттенское расстояние"""
        return abs(cell.x - exit_cell.x) + abs(cell.y - exit_cell.y)
    def find_path(self, maze, start, exit_cell):
        # Приоритетная очередь: (f_score, counter, клетка)
        counter = 0
        open_set = [(0, counter, start)]
        heapq.heapify(open_set)
        came_from = {}
        g_score = {(start.x, start.y): 0}
        f_score = {(start.x, start.y): self._heuristic(start, exit_cell)}
        while open_set:
            current = heapq.heappop(open_set)[2]
            if current == exit_cell:
                return reconstruct_path(came_from, start, exit_cell)
            for neighbor in maze.get_neighbors(current):
                tentative_g = g_score.get((current.x, current.y), float('inf')) + 1
                if tentative_g < g_score.get((neighbor.x, neighbor.y), float('inf')):
                    came_from[(neighbor.x, neighbor.y)] = current
                    g_score[(neighbor.x, neighbor.y)] = tentative_g
                    f = tentative_g + self._heuristic(neighbor, exit_cell)
                    f_score[(neighbor.x, neighbor.y)] = f
                    counter += 1
                    heapq.heappush(open_set, (f, counter, neighbor))
        return []
 # ========== ЭТАП 4: КЛАСС-ОРКЕСТРАТОР ==========
 class SearchStats:
    """Статистика поиска"""
    def __init__(self, time_ms=0, visited_cells=0, path_length=0, path_found=False):
        self.time_ms = time_ms
        self.visited_cells = visited_cells
        self.path_length = path_length
        self.path_found = path_found
    def __repr__(self):
        return f"Stats(time={self.time_ms:.3f}ms, visited={self.visited_cells}, length={self.path_length}, found={self.path_found})"
 class MazeSolver:
    """Оркестратор: принимает лабиринт и стратегию, выполняет поиск"""
    def __init__(self, maze, strategy=None):
        self.maze = maze
        self.strategy = strategy
        self.observers = []
    def set_strategy(self, strategy):
        self.strategy = strategy
    def add_observer(self, observer):
        self.observers.append(observer)
    def _notify(self, event):
        for observer in self.observers:
            observer.update(event)
    def solve(self):
        if self.strategy is None:
            raise ValueError("Стратегия не установлена")
        if self.maze.start is None or self.maze.exit is None:
            raise ValueError("Лабиринт не содержит старт или выход")
        self._notify("Начало поиска пути...")
        start_time = time.perf_counter()
        path = self.strategy.find_path(self.maze, self.maze.start, self.maze.exit)
        end_time = time.perf_counter()
        time_ms = (end_time - start_time) * 1000
        stats = SearchStats(
            time_ms=time_ms,
            visited_cells=len(path) if path else 0,
            path_length=len(path),
            path_found=bool(path)
        )
        self._notify(f"Поиск завершён. Путь найден: {stats.path_found}")
        return path, stats
 # ========== ЭТАП 5: ПАТТЕРНЫ OBSERVER И COMMAND ==========
 class Observer(ABC):
    @abstractmethod
    def update(self, event):
        pass
 class ConsoleView(Observer):
    """Визуализация лабиринта в консоли"""
    def __init__(self):
        self.last_path = []
    def render(self, maze, path=None, player_pos=None):
        """Отрисовывает лабиринт в консоли"""
        # Очистка консоли
        os.system('cls' if os.name == 'nt' else 'clear')
        symbols = {
            'wall': '#',
            'path': '.',
            'start': 'S',
            'exit': 'E',
            'player': 'P',
            'way': 'O'
        }
        for y in range(maze.height):
            line = ""
            for x in range(maze.width):
                cell = maze.get_cell(x, y)
                if player_pos and player_pos == (x, y):
                    line += symbols['player']
                elif cell == maze.start:
                    line += symbols['start']
                elif cell == maze.exit:
                    line += symbols['exit']
                elif cell.is_wall:
                    line += symbols['wall']
                elif path and cell in path:
                    line += symbols['way']
                else:
                    line += symbols['path']
            print(line)
        print(f"\nРазмер: {maze.width}x{maze.height}")
    def update(self, event):
        print(f"[ConsoleView] {event}")
 class Command(ABC):
    @abstractmethod
    def execute(self):
        pass
    @abstractmethod
    def undo(self):
        pass
 class Player:
    """Игрок, который может перемещаться по лабиринту"""
    def __init__(self, start_cell):
        self.current = start_cell
        self.previous = start_cell
    def move_to(self, cell):
        self.previous = self.current
        self.current = cell
    def undo_move(self):
        self.current, self.previous = self.previous, self.current
 class MoveCommand(Command):
    """Команда перемещения игрока"""
    def __init__(self, player, maze, direction):
        self.player = player
        self.maze = maze
        self.direction = direction
        self.executed = False
    def execute(self):
        dx, dy = self.direction
        new_cell = self.maze.get_cell(self.player.current.x + dx, self.player.current.y + dy)
        if new_cell and new_cell.is_passable():
            self.player.move_to(new_cell)
            self.executed = True
            return True
        return False
    def undo(self):
        if self.executed:
            self.player.undo_move()
            self.executed = False
 # ========== ДЕМОНСТРАЦИЯ РАБОТЫ ==========
 def create_test_maze():
    """Создаёт тестовый лабиринт для проверки (если нет файла)"""
    maze = Maze(10, 10)
    # Заполняем стенами
    for y in range(10):
        for x in range(10):
            maze.set_cell(x, y, Cell(x, y, is_wall=True))
    # Создаём коридор
    for x in range(10):
        maze.set_cell(x, 5, Cell(x, 5, is_wall=False))
    maze.set_cell(0, 5, Cell(0, 5, is_start=True))
    maze.set_cell(9, 5, Cell(9, 5, is_exit=True))
    maze.start = maze.get_cell(0, 5)
    maze.exit = maze.get_cell(9, 5)
    return maze
 if __name__ == "__main__":
    print("=== Лабиринт: поиск выхода ===\n")
    # Создаём лабиринт через Builder (или тестовый)
    builder = TextFileMazeBuilder()
    try:
        # Попробуем загрузить из файла
        maze = builder.build_from_file("maze.txt")
        print("Лабиринт загружен из файла maze.txt")
    except FileNotFoundError:
        print("Файл maze.txt не найден. Использую тестовый лабиринт.")
        maze = create_test_maze()
    # Создаём визуализацию
    view = ConsoleView()
    # Тестируем стратегии
    strategies = {
        "BFS": BFSStrategy(),
        "DFS": DFSStrategy(),
        "A*": AStarStrategy()
    }
    solver = MazeSolver(maze)
    solver.add_observer(view)
    results = []
    for name, strategy in strategies.items():
        print(f"\n--- {name} ---")
        solver.set_strategy(strategy)
        path, stats = solver.solve()
        results.append([name, stats.time_ms, stats.visited_cells, stats.path_length, stats.path_found])
        view.render(maze, path)
        print(f"Время: {stats.time_ms:.3f} мс")
        print(f"Длина пути: {stats.path_length}")
        input("\nНажми Enter для продолжения...")
    # Сохраняем результаты
    with open("maze_results.csv", "w", newline='', encoding='utf-8') as f:
        writer = csv.writer(f)
        writer.writerow(["Стратегия", "Время(мс)", "Посещено клеток", "Длина пути", "Путь найден"])
        writer.writerows(results)
    print("\n Результаты сохранены в maze_results.csv")