Merge pull request '[2] Вторая лабораторная работа' (#253) from mylnikovas/2026-rff_mp:task_2 into develop

Reviewed-on: #253
2026-05-30 11:47:57 +00:00 · 2026-05-30 11:47:57 +00:00 · 9b55830b58
commit 9b55830b58
parent 5c7b6b0ac1 a169773089
4 changed files with 403 additions and 0 deletions
--- a/MylnikovAS/task_2/docs/data/results_all.csv
+++ b/MylnikovAS/task_2/docs/data/results_all.csv
@ -0,0 +1,21 @@
 labyrint,strategy,time_ms,passed_cells,path_length
 Small (10x10),BFS,0.1973,59,27
 Small (10x10),DFS,0.1615,49,27
 Small (10x10),AStar,0.2375,50,27
 Small (10x10),Dijkstra,0.2487,60,27
 Empty (50x50),BFS,8.3316,2500,99
 Empty (50x50),DFS,4.6278,1275,1275
 Empty (50x50),AStar,17.5549,2500,99
 Empty (50x50),Dijkstra,14.7128,2500,99
 Middle with dead ends (50x50),BFS,4.8741,1420,1083
 Middle with dead ends (50x50),DFS,4.3282,1275,1275
 Middle with dead ends (50x50),AStar,7.1452,1404,1083
 Middle with dead ends (50x50),Dijkstra,6.0643,1420,1083
 Big (100x100),BFS,17.0733,5590,199
 Big (100x100),DFS,15.1471,4933,4519
 Big (100x100),AStar,31.4644,5140,199
 Big (100x100),Dijkstra,26.7258,5590,199
 Without exit (10x10),BFS,0.0140,5,0
 Without exit (10x10),DFS,0.0124,5,0
 Without exit (10x10),AStar,0.0164,5,0
 Without exit (10x10),Dijkstra,0.0143,5,0
--- a/MylnikovAS/task_2/docs/data/steps_123.py
+++ b/MylnikovAS/task_2/docs/data/steps_123.py
@ -0,0 +1,190 @@
 import time
 import csv
 from collections import deque
 import heapq
 from abc import ABC, abstractmethod
 class Cell:
    def __init__(self, x: int, y: int):
        self.x = x
        self.y = y
        self.isWall = False
        self.isStart = False
        self.isExit = False
        self.weight = 1
    def isPassable(self) -> bool:
        return not self.isWall
    def __lt__(self, other):
        return (self.x, self.y) < (other.x, other.y)
 class Maze:
    def __init__(self, width: int, height: int):
        self.width = width
        self.height = height
        self.cells = [[Cell(x, y) for y in range(height)] for x in range(width)]
        self.start = None
        self.exit = None
    def getCell(self, x: int, y: int) -> Cell:
        if 0 <= x < self.width and 0 <= y < self.height:
            return self.cells[x][y]
        return None
    def getNeighbors(self, cell: Cell):
        neighbors = []
        directions = [(0, -1), (0, 1), (-1, 0), (1, 0)]
        for dx, dy in directions:
            nx, ny = cell.x + dx, cell.y + dy
            neighbor = self.getCell(nx, ny)
            if neighbor and neighbor.isPassable():
                neighbors.append(neighbor)
        return neighbors
 class MazeBuilder(ABC):
    @abstractmethod
    def buildFromStringList(self, lines: list) -> Maze:
        pass
 class TextMazeBuilder(MazeBuilder):
    def buildFromStringList(self, lines: list) -> Maze:
        height = len(lines)
        width = len(lines[0]) if height > 0 else 0
        maze = Maze(width, height)
        for y, line in enumerate(lines):
            for x, char in enumerate(line):
                cell = maze.getCell(x, y)
                if char == '#':
                    cell.isWall = True
                elif char == 'S':
                    cell.isStart = True
                    maze.start = cell
                elif char == 'E':
                    cell.isExit = True
                    maze.exit = cell
                elif char == 'W':
                    cell.weight = 3
                elif char == 'D':
                    cell.weight = 2
        return maze
 class PathFindingStrategy(ABC):
    def __init__(self):
        self.visited_count = 0
    @abstractmethod
    def findPath(self, maze: Maze, start: Cell, exit: Cell) -> list:
        pass
    def _reconstruct_path(self, came_from: dict, start: Cell, exit: Cell) -> list:
        if exit not in came_from:
            return []
        path = []
        current = exit
        while current != start:
            path.append(current)
            current = came_from[current]
        path.append(start)
        path.reverse()
        return path
 class BFSStrategy(PathFindingStrategy):
    def findPath(self, maze: Maze, start: Cell, exit: Cell) -> list:
        self.visited_count = 0
        queue = deque([start])
        came_from = {start: None}
        while queue:
            current = queue.popleft()
            self.visited_count += 1
            if current == exit:
                break
            for neighbor in maze.getNeighbors(current):
                if neighbor not in came_from:
                    queue.append(neighbor)
                    came_from[neighbor] = current
        return self._reconstruct_path(came_from, start, exit)
 class DFSStrategy(PathFindingStrategy):
    def findPath(self, maze: Maze, start: Cell, exit: Cell) -> list:
        self.visited_count = 0
        stack = [start]
        came_from = {start: None}
        while stack:
            current = stack.pop()
            self.visited_count += 1
            if current == exit:
                break
            for neighbor in maze.getNeighbors(current):
                if neighbor not in came_from:
                    stack.append(neighbor)
                    came_from[neighbor] = current
        return self._reconstruct_path(came_from, start, exit)
 class AStarStrategy(PathFindingStrategy):
    def findPath(self, maze: Maze, start: Cell, exit: Cell) -> list:
        self.visited_count = 0
        def heuristic(a, b):
            return abs(a.x - b.x) + abs(a.y - b.y)
        pq = []
        heapq.heappush(pq, (0, start))
        came_from = {start: None}
        g_score = {start: 0}
        while pq:
            _, current = heapq.heappop(pq)
            self.visited_count += 1
            if current == exit:
                break
            for neighbor in maze.getNeighbors(current):
                tentative_g_score = g_score[current] + neighbor.weight
                if neighbor not in g_score or tentative_g_score < g_score[neighbor]:
                    came_from[neighbor] = current
                    g_score[neighbor] = tentative_g_score
                    f_score = tentative_g_score + heuristic(neighbor, exit)
                    heapq.heappush(pq, (f_score, neighbor))
        return self._reconstruct_path(came_from, start, exit)
 class DijkstraStrategy(PathFindingStrategy):
    def findPath(self, maze: Maze, start: Cell, exit: Cell) -> list:
        self.visited_count = 0
        pq = []
        heapq.heappush(pq, (0, start))
        came_from = {start: None}
        g_score = {start: 0}
        while pq:
            current_g, current = heapq.heappop(pq)
            self.visited_count += 1
            if current == exit:
                break
            for neighbor in maze.getNeighbors(current):
                tentative_g_score = g_score[current] + neighbor.weight
                if neighbor not in g_score or tentative_g_score < g_score[neighbor]:
                    came_from[neighbor] = current
                    g_score[neighbor] = tentative_g_score
                    heapq.heappush(pq, (tentative_g_score, neighbor))
        return self._reconstruct_path(came_from, start, exit)
--- a/MylnikovAS/task_2/docs/data/steps_4_and_exp.py
+++ b/MylnikovAS/task_2/docs/data/steps_4_and_exp.py
@ -0,0 +1,192 @@
 class SearchStats:
    def __init__(self, timeMs: float, visitedCells: int, pathLength: int):
        self.timeMs = timeMs
        self.visitedCells = visitedCells
        self.pathLength = pathLength
 class MazeSolver:
    def __init__(self, maze: Maze, strategy: PathFindingStrategy):
        self.maze = maze
        self.strategy = strategy
        self.observers = []
    def setStrategy(self, strategy: PathFindingStrategy):
        self.strategy = strategy
    def addObserver(self, observer):
        self.observers.append(observer)
    def _notify(self, event: str):
        for obs in self.observers:
            obs.update(event)
    def solve(self) -> tuple:
        self._notify("Поиск начат")
        start_time = time.perf_counter()
        path = self.strategy.findPath(self.maze, self.maze.start, self.maze.exit)
        end_time = time.perf_counter()
        time_ms = (end_time - start_time) * 1000
        stats = SearchStats(time_ms, self.strategy.visited_count, len(path))
        self._notify("Поиск завершен")
        return path, stats
 class Observer(ABC):
    @abstractmethod
    def update(self, event: str):
        pass
 class ConsoleView(Observer):
    def update(self, event: str):
        pass
    def render(self, maze: Maze, path: list):
        path_set = set(path)
        for y in range(maze.height):
            row = ""
            for x in range(maze.width):
                cell = maze.getCell(x, y)
                if cell == maze.start:
                    row += "S"
                elif cell == maze.exit:
                    row += "E"
                elif cell in path_set:
                    row += "*"
                elif cell.isWall:
                    row += "#"
                elif cell.weight == 3:
                    row += "W"  # Болото
                elif cell.weight == 2:
                    row += "D"  # Песок
                else:
                    row += "."
            print(row)
 def get_test_mazes():
    builder = TextMazeBuilder()
    mazes = {}
    small = [
        "S.........",
        "#####.####",
        "..........",
        "####.#####",
        "..........",
        "#.#######.",
        "..........",
        "######.###",
        "..........",
        "........XE"
    ]
    small[-1] = small[-1].replace('X', '.')
    mazes["Small (10x10)"] = builder.buildFromStringList(small)
    empty = ["." * 50 for _ in range(50)]
    empty_list = list(empty)
    empty_list[0] = "S" + empty_list[0][1:]
    empty_list[-1] = empty_list[-1][:-1] + "E"
    mazes["Empty (50x50)"] = builder.buildFromStringList(empty_list)
    medium = []
    for y in range(50):
        if y == 0:
            row = "S" + "." * 49
        elif y == 49:
            row = "." * 49 + "E"
        elif y % 2 == 1:
            row = "#" * 45 + "." * 5 if y % 4 == 1 else "." * 5 + "#" * 45
        else:
            row = "." * 50
        medium.append(row)
    mazes["Middle with dead ends (50x50)"] = builder.buildFromStringList(medium)
    large = []
    for y in range(100):
        if y == 0: row = "S" + "." * 99
        elif y == 99: row = "." * 99 + "E"
        elif y % 2 == 1:
            row = ("#" * 9 + ".") * 10
        else:
            row = "." * 100
        large.append(row)
    mazes["Big (100x100)"] = builder.buildFromStringList(large)
    no_exit = [
        "S....#....",
        "##########",
        "##########",
        "##########",
        "##########",
        "##########",
        "##########",
        "##########",
        "##########",
        "######...E"
    ]
    mazes["Without exit (10x10)"] = builder.buildFromStringList(no_exit)
    return mazes
 def main():
    mazes = get_test_mazes()
    strategies = {
        "BFS": BFSStrategy(),
        "DFS": DFSStrategy(),
        "AStar": AStarStrategy(),
        "Dijkstra": DijkstraStrategy()
    }
    output_rows = []
    print("Запуск всех тестов...")
    print("-" * 70)
    for maze_name, maze in mazes.items():
        print(f"Testing: {maze_name}")
        for strat_name, strategy in strategies.items():
            solver = MazeSolver(maze, strategy)
            runs = 5
            total_time = 0
            path = []
            stats = None
            for _ in range(runs):
                path, stats = solver.solve()
                total_time += stats.timeMs
            avg_time = total_time / runs
            output_rows.append([
                maze_name,
                strat_name,
                f"{avg_time:.4f}",
                stats.visitedCells,
                stats.pathLength
            ])
            print(
                f"  -> {strat_name}: Time: {avg_time:.3f}ms | Passed cells: {stats.visitedCells} | Path length: {stats.pathLength}")
        print("-" * 70)
    with open("results_all.csv", "w", newline="", encoding="utf-8") as csvfile:
        writer = csv.writer(csvfile)
        writer.writerow(["labyrint", "strategy", "time_ms", "passed_cells", "path_length"])
        writer.writerows(output_rows)
    print("Все замеры успешно выполнены! Результаты сохранены в 'results_all.csv'")
 if __name__ == "__main__":
    main()
--- a/MylnikovAS/task_2/docs/Отчёт
+++ b/MylnikovAS/task_2/docs/Отчёт