webots-module-b/nav_test.py

#!/usr/bin/env python3

import rclpy
from rclpy.node import Node
from geometry_msgs.msg import Twist
from sensor_msgs.msg import Image
from std_msgs.msg import String
from nav_msgs.msg import Odometry

import cv2
from cv_bridge import CvBridge
import numpy as np
import math
import threading
import time
from collections import deque

# ── Настраиваемые коэффициенты ──────────────────────────────────────────────
K_VISUAL       = 0.8    # П-коэффициент визуального cross-track (агрессивная коррекция)
K_VISUAL_DECAY = 0.92  # Коэффициент затухания визуальной ошибки (память)
K_HEADING      = 0.6    # П-регулятор удержания курса
K_CROSS_P      = 2.0    # Пропорциональный коэффициент odom cross-track
MAX_ANGULAR    = 0.35   # Максимальная скорость поворота (рад/с)
K_TURN         = 1.5    # П-регулятор поворота на месте
DRIVE_SPEED    = 0.3    # Скорость движения вперёд (м/с)
CELL_SIZE_M    = 0.65   # Предполагаемая длина одной клетки поля (м)
# ────────────────────────────────────────────────────────────────────────────


class RMC2Navigator(Node):
    FIELD_ROWS = 6
    FIELD_COLS = 6
    
    def __init__(self):
        super().__init__('rmc2_navigator')

        self.cmd_pub = self.create_publisher(Twist, '/RMC2/cmd_vel', 10)
        self.create_subscription(String, '/RMC2/aruco_id', self.aruco_id_cb, 10)
        self.create_subscription(Image, '/RMC2/camera_bottom/image_color', self.camera_cb, 10)
        self.create_subscription(Odometry, '/RMC2/odometry', self.odom_cb, 10)

        self.bridge = CvBridge()

        self.current_marker_id = None
        self.target_marker_id  = None
        self.current_yaw = 0.0
        self.current_x   = 0.0
        self.current_y   = 0.0
        self.target_yaw  = 0.0

        self.state = 'IDLE'

        self.total_cells        = 0
        self.drive_start_x      = 0.0
        self.drive_start_y      = 0.0
        self.start_marker_id    = None
        
        self.blocked_cells = set()
        self.waypoints = []
        self.waypoint_idx = 0

        # ArUco
        try:
            self.aruco_params = cv2.aruco.DetectorParameters_create()  # old API (< 4.7)
        except AttributeError:
            self.aruco_params = cv2.aruco.DetectorParameters()          # new API (>= 4.7)

        try:
            self.aruco_dict = cv2.aruco.Dictionary_get(cv2.aruco.DICT_6X6_50)
        except AttributeError:
            self.aruco_dict = cv2.aruco.getPredefinedDictionary(cv2.aruco.DICT_6X6_50)

        self._centering_ok_count = 0
        self.latest_image = None
        self._debug_frame_idx = 0
        self._yaw_reference = None  # Базовый yaw при старте движения
        self._cross_track_ref_marker = None  # Маркер, от которого ведётся odom cross-track
        self._visual_err_x_memory = 0.0  # Память визуальной коррекции

        # Таймер главного цикла (20 Гц)
        self.timer = self.create_timer(0.05, self.control_loop)

        # Поток ввода пользователя
        self.input_thread = threading.Thread(target=self.user_input_thread, daemon=True)
        self.input_thread.start()

        self.get_logger().info("Узел навигации RMC2 запущен. Ожидание стартового маркера...")

    # ── Колбэки ─────────────────────────────────────────────────────────────

    def aruco_id_cb(self, msg):
        try:
            clean_id = msg.data.replace('aruco_', '')
            self.current_marker_id = int(clean_id)
        except ValueError:
            pass

    def odom_cb(self, msg):
        self.current_x = msg.pose.pose.position.x
        self.current_y = msg.pose.pose.position.y

        q = msg.pose.pose.orientation
        siny_cosp = 2 * (q.w * q.z + q.x * q.y)
        cosy_cosp = 1 - 2 * (q.y * q.y + q.z * q.z)
        odom_yaw = math.atan2(siny_cosp, cosy_cosp)

        # Компас жестко привязан к глобальным осям (отключен _yaw_reference)
        self.current_yaw = self.normalize_angle(odom_yaw)

    def camera_cb(self, msg):
        try:
            img_array = np.frombuffer(msg.data, dtype=np.uint8)
            if msg.encoding == 'bgra8':
                img = img_array.reshape((msg.height, msg.width, 4))
                self.latest_image = cv2.cvtColor(img, cv2.COLOR_BGRA2BGR)
            elif msg.encoding == 'bgr8':
                self.latest_image = img_array.reshape((msg.height, msg.width, 3)).copy()
            elif msg.encoding == 'rgb8':
                img = img_array.reshape((msg.height, msg.width, 3))
                self.latest_image = cv2.cvtColor(img, cv2.COLOR_RGB2BGR)
            else:
                cv_image = self.bridge.imgmsg_to_cv2(msg, desired_encoding='bgr8')
                self.latest_image = cv_image.copy()
        except Exception as e:
            self.get_logger().error(f"Ошибка чтения кадра: {e}")

    # ── Ввод пользователя ───────────────────────────────────────────────────

    def user_input_thread(self):
        while rclpy.ok():
            if self.state == 'IDLE':
                if self.current_marker_id is None:
                    time.sleep(1)
                    continue
                try:
                    print(f"\n--- Робот над маркером: {self.current_marker_id} ---")
                    print("Заблокированные клетки:", sorted(self.blocked_cells))
                    target = input("Введите ID целевой метки (или 'b <id>' для блокировки): ").strip()
                    if target.startswith('b '):
                        blocked_id = int(target[2:])
                        if blocked_id in self.blocked_cells:
                            self.blocked_cells.remove(blocked_id)
                            print(f"Клетка {blocked_id} разблокирована")
                        else:
                            self.blocked_cells.add(blocked_id)
                            print(f"Клетка {blocked_id} заблокирована")
                        continue
                    self.target_marker_id = int(target)
                    self.start_navigation()
                except ValueError:
                    print("Ошибка: введите целое число.")
            else:
                time.sleep(0.5)

    # ── Вспомогательные функции ─────────────────────────────────────────────

    def get_marker_coords(self, marker_id):
        row = marker_id % 6
        col = marker_id // 6
        x = col * 1.0
        y = 5 - row * 1.0
        return x, y

    def marker_to_grid(self, marker_id):
        return (marker_id % 6, marker_id // 6)
    
    def grid_to_marker(self, row, col):
        return col * 6 + row

    def get_neighbors(self, row, col):
        neighbors = []
        for dr, dc in [(-1, 0), (1, 0), (0, -1), (0, 1)]:
            nr, nc = row + dr, col + dc
            if 0 <= nr < self.FIELD_ROWS and 0 <= nc < self.FIELD_COLS:
                mid = self.grid_to_marker(nr, nc)
                if mid not in self.blocked_cells:
                    neighbors.append((nr, nc))
        return neighbors

    def find_path_bfs(self, start_id, goal_id):
        if goal_id in self.blocked_cells:
            return None
        start = self.marker_to_grid(start_id)
        goal = self.marker_to_grid(goal_id)
        queue = deque([(start, [start])])
        visited = {start}
        while queue:
            (row, col), path = queue.popleft()
            if (row, col) == goal:
                return path
            for nr, nc in self.get_neighbors(row, col):
                if (nr, nc) not in visited:
                    visited.add((nr, nc))
                    queue.append(((nr, nc), path + [(nr, nc)]))
        return None

    def normalize_angle(self, angle):
        return math.atan2(math.sin(angle), math.cos(angle))

    def start_navigation(self):
        path = self.find_path_bfs(self.current_marker_id, self.target_marker_id)
        if path is None:
            print(f"Маршрут до {self.target_marker_id} не найден (заблокирован или нет пути)")
            return
        
        self.waypoints = [self.grid_to_marker(r, c) for r, c in path]
        self.waypoint_idx = 1
        
        print(f"Маршрут: {' → '.join(map(str, self.waypoints))}")
        
        self._navigate_to_next_waypoint()

    def _navigate_to_next_waypoint(self):
        if self.waypoint_idx >= len(self.waypoints):
            self.get_logger().info("Все точки маршрута пройдены!")
            self.state = 'IDLE'
            return
        
        next_marker = self.waypoints[self.waypoint_idx]
        cx, cy = self.get_marker_coords(self.current_marker_id)
        tx, ty = self.get_marker_coords(next_marker)
        dx, dy = tx - cx, ty - cy
        
        dist = math.sqrt(dx*dx + dy*dy)
        if dist < 0.01:
            self.waypoint_idx += 1
            self._navigate_to_next_waypoint()
            return
        
        self.get_logger().info(f"DEBUG: {self.current_marker_id}({cx:.1f},{cy:.1f}) -> {next_marker}({tx:.1f},{ty:.1f}), d=({dx:.1f},{dy:.1f})")
        self.get_logger().info(f"DEBUG: current_yaw={math.degrees(self.current_yaw):.1f}°")
        raw_yaw = math.atan2(dy, dx)
        # Угол строго 180° может быть +π или -π, выбираем ближе к текущему yaw
        raw_yaw_normalized = math.atan2(dy, dx)  # в диапазоне [-π, π]
        # Проверяем оба варианта: raw_yaw и raw_yaw ± 2π
        candidates = [raw_yaw_normalized - 2*math.pi, raw_yaw_normalized, raw_yaw_normalized + 2*math.pi]
        # Выбираем ближайший к current_yaw
        best_yaw = min(candidates, key=lambda y: abs(y - self.current_yaw))
        self.target_yaw = best_yaw
        self.get_logger().info(f"DEBUG: target_yaw={math.degrees(self.target_yaw):.1f}°")
        self.total_cells = 1
        self.start_marker_id = self.current_marker_id
        self._centering_ok_count = 0
        
        self._line_start_x, self._line_start_y = self.get_marker_coords(self.current_marker_id)
        self._line_perp_yaw = self.target_yaw + math.pi / 2.0
        self._cross_track_ref_marker = self.current_marker_id
        self._visual_err_x_memory = 0.0
        
        self.get_logger().info(
            f"Еду к точке {next_marker} (waypoint {self.waypoint_idx}/{len(self.waypoints)-1}), "
            f"курс {math.degrees(self.target_yaw):.1f}°")
        self.state = 'TURN_TO_TARGET'

    def _cross_track_error(self, x, y):
        """
        Рассчитывает signed cross-track error — расстояние от текущей позиции
        до идеальной линии движения (с указанием знака: + справа, − слева).

        Линия: проходит через (_line_start_x, _line_start_y) под углом target_yaw.
        """
        dx = x - self._line_start_x
        dy = y - self._line_start_y
        # Проекция на нормаль к линии (перпендикуляр target_yaw)
        cross_track = -dx * math.sin(self.target_yaw) + dy * math.cos(self.target_yaw)
        return cross_track

    # ── ArUco-детектор (общий, переиспользуемый) ────────────────────────────

    def _detect_markers(self):
        """Детектирует маркеры на последнем кадре камеры.

        Возвращает (ids_list, corners_list, img_w, img_h)
        или (None, None, 0, 0) при ошибке / нет кадра.
        """
        if self.latest_image is None:
            return None, None, 0, 0
        try:
            frame = self.latest_image.copy()
            gray  = cv2.cvtColor(frame, cv2.COLOR_BGR2GRAY)
            gray  = np.ascontiguousarray(gray, dtype=np.uint8)
            h, w  = gray.shape

            scale = min(1.0, 640.0 / w)
            small = cv2.resize(gray, (0, 0), fx=scale, fy=scale,
                               interpolation=cv2.INTER_AREA) if scale < 1.0 else gray

            corners, ids, _ = cv2.aruco.detectMarkers(
                small, self.aruco_dict, parameters=self.aruco_params)

            if ids is not None and scale < 1.0:
                corners = [c / scale for c in corners]

            if ids is None:
                return [], [], w, h

            return ids.flatten().tolist(), corners, w, h
        except Exception as e:
            self.get_logger().error(f"Ошибка детекции: {e}")
            return None, None, 0, 0

    def _marker_offset(self, marker_id, ids_list, corners, img_w, img_h):
        """Возвращает нормализованные (err_x, err_y) ∈ [-1, 1] для заданного маркера
        или (None, None) если маркер не найден.

        err_x > 0: маркер правее центра камеры (робот левее центра маркера).
        err_y > 0: маркер ниже центра камеры (маркер «за» роботом).
        """
        if not ids_list or marker_id not in ids_list:
            return None, None
        idx   = ids_list.index(marker_id)
        pts   = corners[idx][0]
        mcx   = np.mean(pts[:, 0])
        mcy   = np.mean(pts[:, 1])
        err_x = (mcx - img_w / 2.0) / (img_w / 2.0)
        err_y = (mcy - img_h / 2.0) / (img_h / 2.0)
        return err_x, err_y

    # ── Главный цикл управления (20 Гц) ─────────────────────────────────────

    def control_loop(self):
        if self.state == 'IDLE':
            return

        twist = Twist()

        # ── Поворот на месте (к цели или финальное выравнивание) ────────────
        if self.state in ('TURN_TO_TARGET', 'ALIGN_ORIENTATION'):
            yaw_err = self.normalize_angle(self.target_yaw - self.current_yaw)

            if abs(yaw_err) > 0.035:  # ~2°
                # Замедляемся при подходе к цели: ниже 5° уменьшаем усиление
                gain = K_TURN if abs(yaw_err) > 0.087 else K_TURN * 0.6
                twist.angular.z = gain * yaw_err
                twist.angular.z = max(-1.0, min(1.0, twist.angular.z))
                if not hasattr(self, '_log_counter'):
                    self._log_counter = 0
                self._log_counter += 1
                if self._log_counter % 10 == 1:
                    self.get_logger().info(
                        f"TURN: target={math.degrees(self.target_yaw):.1f}°, "
                        f"current={math.degrees(self.current_yaw):.1f}°, "
                        f"err={math.degrees(yaw_err):.1f}°, cmd={twist.angular.z:.2f}")
            else:
                if self.state == 'TURN_TO_TARGET':
                    self.get_logger().info(
                        f"Курс взят ({math.degrees(self.target_yaw):.1f}°). "
                        f"Еду {self.total_cells} кл. прямо.")
                    self.state = 'DRIVE_STRAIGHT'
                    self.drive_start_x = self.current_x
                    self.drive_start_y = self.current_y
                else:
                    self.get_logger().info("Ориентация выровнена!")
                    self.current_marker_id = self.target_marker_id
                    self.state = 'IDLE'

        elif self.state == 'DRIVE_STRAIGHT':
            if self.current_marker_id == self.target_marker_id:
                self.get_logger().info("Финальный маркер подтверждён!")
                self.waypoint_idx += 1
                if self.waypoint_idx < len(self.waypoints):
                    self._navigate_to_next_waypoint()
                else:
                    self.state = 'IDLE'
                self.cmd_pub.publish(twist)
                return

            ids_list, corners, img_w, img_h = self._detect_markers()

            if self.waypoint_idx < len(self.waypoints):
                next_wp = self.waypoints[self.waypoint_idx]
                if ids_list is not None and next_wp in ids_list:
                    self.get_logger().info(f"Промежуточный waypoint {next_wp} достигнут")
                    self.current_marker_id = next_wp
                    self._line_start_x, self._line_start_y = self.get_marker_coords(next_wp)
                    self.waypoint_idx += 1
                    if self.waypoint_idx < len(self.waypoints):
                        self._navigate_to_next_waypoint()
                    else:
                        self.state = 'IDLE'
                    self.cmd_pub.publish(twist)
                    return

            if ids_list is not None and self.target_marker_id in ids_list:
                ex, ey = self._marker_offset(self.target_marker_id, ids_list, corners, img_w, img_h)
                if ey is not None and ey > -0.2:
                    self.get_logger().info(
                        f"Финальный маркер {self.target_marker_id} в кадре (err_y={ey:.2f}).")
                    self.waypoint_idx += 1
                    if self.waypoint_idx < len(self.waypoints):
                        self._navigate_to_next_waypoint()
                    else:
                        self.state = 'IDLE'
                    self.cmd_pub.publish(twist)
                    return

            visual_err_x = None
            if ids_list:
                best_dist = float('inf')
                for mid in ids_list:
                    ex, ey = self._marker_offset(mid, ids_list, corners, img_w, img_h)
                    if ex is None:
                        continue
                    dist = abs(ex) + abs(ey)
                    if dist < best_dist:
                        best_dist = dist
                        visual_err_x = ex
            
            if visual_err_x is not None:
                self._visual_err_x_memory = visual_err_x
            else:
                self._visual_err_x_memory *= K_VISUAL_DECAY

            base_yaw_err = self.normalize_angle(self.target_yaw - self.current_yaw)

            use_visual = abs(self._visual_err_x_memory) > 0.01
            if use_visual:
                twist.linear.x = DRIVE_SPEED
                twist.angular.z = K_HEADING * base_yaw_err - K_VISUAL * self._visual_err_x_memory
                twist.angular.z = max(-MAX_ANGULAR, min(MAX_ANGULAR, twist.angular.z))
            else:
                twist.linear.x = DRIVE_SPEED
                twist.angular.z = K_HEADING * base_yaw_err
                twist.angular.z = max(-MAX_ANGULAR, min(MAX_ANGULAR, twist.angular.z))

            if not hasattr(self, '_cross_log_counter'):
                self._cross_log_counter = 0
            self._cross_log_counter += 1
            if self._cross_log_counter % 10 == 0:
                self.get_logger().info(
                    f"[VIS-MEM] err_x={self._visual_err_x_memory:+.3f}, "
                    f"yaw={math.degrees(base_yaw_err):+.1f}°, tw.z={twist.angular.z:+.3f}")

        # ── Визуальное центрирование над финальным маркером ─────────────────
        elif self.state == 'CENTER_MARKER':
            if self.latest_image is None:
                self.get_logger().warn("CENTER_MARKER: нет кадра", throttle_duration_sec=1.0)
                return

            try:
                frame = self.latest_image.copy()
                gray  = cv2.cvtColor(frame, cv2.COLOR_BGR2GRAY)
                gray  = np.ascontiguousarray(gray, dtype=np.uint8)

                self._debug_frame_idx += 1
                if self._debug_frame_idx % 40 == 1:
                    cv2.imwrite('/tmp/aruco_debug_gray.png', gray)
                    self.get_logger().info(
                        f"DEBUG кадр #{self._debug_frame_idx}: shape={gray.shape}, "
                        f"mean={gray.mean():.1f} → /tmp/aruco_debug_gray.png")

                h_orig, w_orig = gray.shape
                scale = min(1.0, 640.0 / w_orig)
                if scale < 1.0:
                    small = cv2.resize(gray, (0, 0), fx=scale, fy=scale,
                                       interpolation=cv2.INTER_AREA)
                else:
                    small = gray

                corners, ids, _ = cv2.aruco.detectMarkers(
                    small, self.aruco_dict, parameters=self.aruco_params)

                if ids is not None and scale < 1.0:
                    corners = [c / scale for c in corners]

                target_corners = None
                if ids is not None:
                    found_ids = ids.flatten().tolist()
                    for i in range(len(ids)):
                        if ids[i][0] == self.target_marker_id:
                            target_corners = corners[i][0]
                            break
                    if target_corners is None:
                        self.get_logger().warn(
                            f"CENTER_MARKER: вижу {found_ids}, цель={self.target_marker_id} не найдена",
                            throttle_duration_sec=1.0)
                else:
                    self.get_logger().warn(
                        "CENTER_MARKER: маркеры не найдены", throttle_duration_sec=1.0)
                    self._centering_ok_count = 0

                if target_corners is not None:
                    mcx = np.mean(target_corners[:, 0])
                    mcy = np.mean(target_corners[:, 1])
                    h, w = gray.shape

                    err_x = (mcx - w / 2.0) / (w / 2.0)   # нормализованная ошибка X
                    err_y = (mcy - h / 2.0) / (h / 2.0)   # нормализованная ошибка Y

                    twist.linear.x  = -0.12 * err_y
                    twist.angular.z = -0.25 * err_x

                    twist.linear.x  = max(-0.08, min(0.08, twist.linear.x))
                    twist.angular.z = max(-0.20, min(0.20, twist.angular.z))

                    if abs(err_x) < 0.05 and abs(err_y) < 0.05:
                        self._centering_ok_count += 1
                        if self._centering_ok_count >= 5:
                            self.get_logger().info(
                                f"Центрирование завершено (err={err_x:.2f},{err_y:.2f}). "
                                f"Выравниваю ориентацию.")
                            self._centering_ok_count = 0
                            self.state = 'ALIGN_ORIENTATION'
                    else:
                        self._centering_ok_count = 0

            except Exception as e:
                self.get_logger().error(f"OpenCV ошибка: {e}")

        self.cmd_pub.publish(twist)


def main(args=None):
    rclpy.init(args=args)
    navigator = RMC2Navigator()
    try:
        rclpy.spin(navigator)
    except KeyboardInterrupt:
        pass
    finally:
        navigator.cmd_pub.publish(Twist())
        navigator.destroy_node()
        rclpy.shutdown()


if __name__ == '__main__':
    main()