GeCaoAPP.git - Gitblit

			@@ -1,1124 +1,634 @@
			package lujing;

			import java.util.*;
			import java.util.regex.*;
			import java.util.stream.Collectors;


			/**
			* 异形草地路径规划 - 优化完善版
			* 采用更完善的算法：
			* 1. 使用多边形裁剪库计算更精确的内缩边界
			* 2. 使用扫描线填充算法生成更优化的路径
			* 3. 使用可见图算法寻找最优绕行路径
			* 4. 使用路径优化算法减少空行和转弯
			* 异形草地路径规划 - 含障碍物版
			* 功能：在地块内部避开障碍物，生成连续弓字形割草路径
			*/
			public class YixinglujingHaveObstacel {

			private static final double EPS = 1e-10;
			private static final double MIN_SEG_LEN = 0.01; // 忽略小于1cm的碎线
			private static final double CORNER_THRESHOLD = Math.toRadians(30); // 30度以下的角度合并

			public static List<PathSegment> planPath(String coordinates, String obstaclesStr, String widthStr, String marginStr) {
			try {
			// 解析输入参数
			double mowWidth = Double.parseDouble(widthStr);
			double safeMargin = Double.parseDouble(marginStr);

			// 解析多边形和障碍物
			List<Point> boundary = parseCoordinates(coordinates);
			if (boundary.size() < 3) {
			throw new IllegalArgumentException("地块边界至少需要3个点");
			}

			// 确保多边形为逆时针方向
			makeCCW(boundary);

			// 解析障碍物并外扩
			List<Obstacle> obstacles = parseAndExpandObstacles(obstaclesStr, safeMargin);

			// 生成内缩作业边界（考虑障碍物）
			List<Point> workingArea = computeWorkingArea(boundary, obstacles, safeMargin);
			if (workingArea.isEmpty()) {
			return new ArrayList<>();
			}

			// 生成完整的全覆盖路径（不考虑障碍物）
			List<PathSegment> fullPath = generateCompleteCoverage(workingArea, mowWidth);

			// 用障碍物裁剪路径
			List<PathSegment> clippedPath = clipPathWithObstacles(fullPath, obstacles);

			// 连接和优化路径（限制在作业边界内）
			List<PathSegment> finalPath = connectAndOptimizePath(clippedPath, obstacles, mowWidth, workingArea);

			return finalPath;

			} catch (Exception e) {
			System.err.println("路径规划错误: " + e.getMessage());
			e.printStackTrace();
			return new ArrayList<>();
			public static List<PathSegment> planPath(String coordinates, String obstaclesStr,
			String widthStr, String marginStr) {
			// 1. 解析参数
			List<Point> rawPoints = parseCoordinates(coordinates);
			if (rawPoints.size() < 3) return new ArrayList<>();

			double mowWidth = Double.parseDouble(widthStr);
			double safeMargin = Double.parseDouble(marginStr);

			// 解析障碍物
			List<Obstacle> obstacles = parseObstacles(obstaclesStr);

			// 2. 预处理：确保边界逆时针
			ensureCounterClockwise(rawPoints);

			// 3. 生成内缩多边形（安全边界）
			List<Point> boundary = getInsetPolygon(rawPoints, safeMargin);
			if (boundary.size() < 3) return new ArrayList<>();

			// 4. 外扩障碍物（安全边距）
			List<Obstacle> expandedObstacles = expandObstacles(obstacles, safeMargin);

			// 5. 确定最优作业角度
			double bestAngle = findOptimalAngle(boundary);

			// 6. 获取首个作业点，用于对齐围边起点
			Point firstScanStart = getFirstScanPoint(boundary, mowWidth, bestAngle);

			// 7. 对齐围边
			List<Point> alignedBoundary = alignBoundaryStart(boundary, firstScanStart);

			// 8. 第一阶段：围边路径
			List<PathSegment> finalPath = new ArrayList<>();
			for (int i = 0; i < alignedBoundary.size(); i++) {
			Point pStart = alignedBoundary.get(i);
			Point pEnd = alignedBoundary.get((i + 1) % alignedBoundary.size());
			finalPath.add(new PathSegment(pStart, pEnd, true));
			}

			// 9. 第二阶段：生成内部扫描路径（考虑障碍物）
			Point lastEdgePos = alignedBoundary.get(0);
			List<PathSegment> scanPath = generateGlobalScanPathWithObstacles(
			boundary, expandedObstacles, mowWidth, bestAngle, lastEdgePos);

			finalPath.addAll(scanPath);

			return finalPath;
			}

			/**
			* 计算作业区域（考虑障碍物）
			* 生成带障碍物的扫描路径
			*/
			private static List<Point> computeWorkingArea(List<Point> boundary, List<Obstacle> obstacles, double margin) {
			// 首先生成内缩边界
			List<Point> offsetBoundary = offsetPolygon(boundary, -margin);
			private static List<PathSegment> generateGlobalScanPathWithObstacles(
			List<Point> polygon, List<Obstacle> obstacles,
			double width, double angle, Point startPos) {

			if (obstacles.isEmpty()) {
			return offsetBoundary;
			}
			// 1. 生成原始扫描线（无障碍物）
			List<PathSegment> originalSegments = generateGlobalScanPath(polygon, width, angle, startPos);

			// 如果存在障碍物，从内缩边界中减去障碍物区域
			// 简化处理：工作区域仍以内缩边界为主，具体裁剪在路径层面完成
			makeCCW(offsetBoundary);
			return offsetBoundary;
			}

			/**
			* 生成完整的全覆盖路径
			*/
			private static List<PathSegment> generateCompleteCoverage(List<Point> polygon, double width) {
			List<PathSegment> path = new ArrayList<>();

			// 1. 生成边界路径
			List<PathSegment> borderPath = generateBorderPath(polygon, width);
			path.addAll(borderPath);

			// 2. 生成扫描线路径
			List<PathSegment> scanLines = generateScanLines(polygon, width);

			// 3. 连接扫描线
			if (!scanLines.isEmpty()) {
			Point currentPos = path.isEmpty() ? scanLines.get(0).start :
			path.get(path.size() - 1).end;

			for (PathSegment scanLine : scanLines) {
			// 添加空行连接
			if (distance(currentPos, scanLine.start) > MIN_SEG_LEN) {
			path.add(new PathSegment(currentPos, scanLine.start, false));
			}
			path.add(scanLine);
			currentPos = scanLine.end;
			}

			// 连接回起点
			if (distance(currentPos, path.get(0).start) > MIN_SEG_LEN) {
			path.add(new PathSegment(currentPos, path.get(0).start, false));
			}
			}

			return path;
			}

			/**
			* 生成边界路径（一圈或多圈）
			*/
			private static List<PathSegment> generateBorderPath(List<Point> polygon, double width) {
			List<PathSegment> border = new ArrayList<>();

			// 根据宽度确定需要多少圈边界
			int borderPasses = 1; // 至少一圈
			if (width < 0.3) {
			borderPasses = 2; // 宽度较小，增加边界圈数
			}

			for (int pass = 0; pass < borderPasses; pass++) {
			double offset = pass * width;
			List<Point> offsetPoly = offsetPolygon(polygon, -offset);

			if (offsetPoly.size() < 3) break;

			for (int i = 0; i < offsetPoly.size(); i++) {
			Point start = offsetPoly.get(i);
			Point end = offsetPoly.get((i + 1) % offsetPoly.size());
			border.add(new PathSegment(start, end, true));
			}
			}

			return border;
			}

			/**
			* 生成扫描线路径
			*/
			private static List<PathSegment> generateScanLines(List<Point> polygon, double width) {
			List<PathSegment> scanLines = new ArrayList<>();

			// 计算最优扫描方向
			double optimalAngle = calculateOptimalScanAngle(polygon);

			// 旋转多边形到扫描方向
			List<Point> rotatedPoly = rotatePolygon(polygon, -optimalAngle);

			// 计算包围盒
			Bounds bounds = calculateBounds(rotatedPoly);

			// 生成扫描线
			boolean leftToRight = true;
			for (double y = bounds.minY + width / 2; y <= bounds.maxY - width / 2 + EPS; y += width) {
			// 获取水平线与多边形的交点
			List<Double> intersections = getHorizontalIntersections(rotatedPoly, y);

			if (intersections.size() < 2) continue;

			// 交点排序并成对处理
			Collections.sort(intersections);
			List<PathSegment> lineSegments = new ArrayList<>();

			for (int i = 0; i < intersections.size(); i += 2) {
			if (i + 1 >= intersections.size()) break;

			double x1 = intersections.get(i);
			double x2 = intersections.get(i + 1);

			if (x2 - x1 < MIN_SEG_LEN) continue;

			// 旋转回原始坐标系
			Point start = rotatePoint(new Point(x1, y), optimalAngle);
			Point end = rotatePoint(new Point(x2, y), optimalAngle);

			lineSegments.add(new PathSegment(start, end, true));
			}

			// 方向交替
			if (!leftToRight) {
			Collections.reverse(lineSegments);
			for (PathSegment seg : lineSegments) {
			Point temp = seg.start;
			seg.start = seg.end;
			seg.end = temp;
			}
			}

			scanLines.addAll(lineSegments);
			leftToRight = !leftToRight;
			}

			return scanLines;
			}

			/**
			* 用障碍物裁剪路径
			*/
			private static List<PathSegment> clipPathWithObstacles(List<PathSegment> path, List<Obstacle> obstacles) {
			if (obstacles.isEmpty()) return path;

			List<PathSegment> clipped = new ArrayList<>();

			for (PathSegment segment : path) {
			List<PathSegment> remaining = new ArrayList<>();
			remaining.add(segment);

			// 依次用每个障碍物裁剪
			for (Obstacle obstacle : obstacles) {
			List<PathSegment> temp = new ArrayList<>();
			for (PathSegment seg : remaining) {
			temp.addAll(obstacle.clipSegment(seg));
			}
			remaining = temp;
			}

			clipped.addAll(remaining);
			}

			return clipped;
			}

			/**
			* 连接和优化路径
			*/
			private static List<PathSegment> connectAndOptimizePath(List<PathSegment> segments,
			List<Obstacle> obstacles,
			double width,
			List<Point> workingArea) {
			if (segments.isEmpty()) return new ArrayList<>();

			// 1. 先按类型分组：割草段和连接段
			List<PathSegment> mowingSegments = segments.stream()
			.filter(s -> s.isMowing)
			.collect(Collectors.toList());

			// 2. 使用旅行商问题(TSP)的近似算法连接割草段
			List<PathSegment> connectedPath = connectSegmentsTSP(mowingSegments, obstacles, workingArea);

			// 3. 优化路径：合并小段、平滑转角
			connectedPath = optimizePath(connectedPath, width);

			return connectedPath;
			}

			/**
			* 使用旅行商问题近似算法连接路径段
			*/
			private static List<PathSegment> connectSegmentsTSP(List<PathSegment> segments, List<Obstacle> obstacles, List<Point> workingArea) {
			List<PathSegment> connected = new ArrayList<>();

			if (segments.isEmpty()) return connected;

			// 构建点集（所有线段的端点）
			List<Point> points = new ArrayList<>();
			for (PathSegment seg : segments) {
			points.add(seg.start);
			points.add(seg.end);
			}

			// 使用最近邻算法构建路径
			boolean[] visited = new boolean[segments.size()];
			Point currentPos = segments.get(0).start;

			while (true) {
			int bestIdx = -1;
			double bestDist = Double.MAX_VALUE;
			boolean useStart = true;

			// 寻找最近的未访问线段
			for (int i = 0; i < segments.size(); i++) {
			if (visited[i]) continue;

			PathSegment seg = segments.get(i);
			double distToStart = distance(currentPos, seg.start);
			double distToEnd = distance(currentPos, seg.end);

			if (distToStart < bestDist) {
			bestDist = distToStart;
			bestIdx = i;
			useStart = true;
			}
			if (distToEnd < bestDist) {
			bestDist = distToEnd;
			bestIdx = i;
			useStart = false;
			}
			}

			if (bestIdx == -1) break;

			// 添加连接路径
			PathSegment bestSeg = segments.get(bestIdx);
			Point targetPoint = useStart ? bestSeg.start : bestSeg.end;

			if (distance(currentPos, targetPoint) > MIN_SEG_LEN) {
			// 寻找安全连接路径（受作业边界限制）
			List<PathSegment> detour = findSafePath(currentPos, targetPoint, obstacles, workingArea);
			connected.addAll(detour);
			}

			// 添加割草线段（可能反转方向）
			PathSegment toAdd = bestSeg;
			if (!useStart) {
			toAdd = new PathSegment(bestSeg.end, bestSeg.start, true);
			}
			connected.add(toAdd);

			currentPos = toAdd.end;
			visited[bestIdx] = true;
			}

			return connected;
			}

			/**
			* 寻找安全路径（A*算法）
			*/
			private static List<PathSegment> findSafePath(Point start, Point end, List<Obstacle> obstacles, List<Point> workingArea) {
			// 如果直线路径安全，直接使用
			if (isLineSafe(start, end, obstacles, workingArea)) {
			List<PathSegment> direct = new ArrayList<>();
			direct.add(new PathSegment(start, end, false));
			return direct;
			}

			// 否则使用A*算法寻找绕行路径
			return aStarPathFinding(start, end, obstacles, workingArea);
			}

			/**
			* A*算法路径寻找
			*/
			private static List<PathSegment> aStarPathFinding(Point start, Point end, List<Obstacle> obstacles, List<Point> workingArea) {
			// 简化的A*算法实现
			// 这里我们使用障碍物边界上的关键点作为路径节点

			List<Point> nodes = new ArrayList<>();
			nodes.add(start);
			nodes.add(end);

			// 添加障碍物的顶点作为候选节点
			for (Obstacle obs : obstacles) {
			nodes.addAll(obs.getKeyPoints());
			}
			// 添加作业边界顶点，允许贴边绕行
			if (workingArea != null && workingArea.size() >= 3) {
			nodes.addAll(workingArea);
			}

			// 构建图
			Map<Point, Map<Point, Double>> graph = new HashMap<>();
			for (Point p1 : nodes) {
			graph.put(p1, new HashMap<>());
			for (Point p2 : nodes) {
			if (p1 == p2) continue;
			if (isLineSafe(p1, p2, obstacles, workingArea)) {
			graph.get(p1).put(p2, distance(p1, p2));
			}
			}
			}

			// A*搜索
			Map<Point, Double> gScore = new HashMap<>();
			Map<Point, Double> fScore = new HashMap<>();
			Map<Point, Point> cameFrom = new HashMap<>();
			PriorityQueue<Point> openSet = new PriorityQueue<>(
			Comparator.comparingDouble(p -> fScore.getOrDefault(p, Double.MAX_VALUE))
			);

			gScore.put(start, 0.0);
			fScore.put(start, heuristic(start, end));
			openSet.add(start);

			while (!openSet.isEmpty()) {
			Point current = openSet.poll();

			if (current.equals(end)) {
			return reconstructPath(cameFrom, current);
			}

			for (Map.Entry<Point, Double> neighborEntry : graph.getOrDefault(current, new HashMap<>()).entrySet()) {
			Point neighbor = neighborEntry.getKey();
			double tentativeGScore = gScore.get(current) + neighborEntry.getValue();

			if (tentativeGScore < gScore.getOrDefault(neighbor, Double.MAX_VALUE)) {
			cameFrom.put(neighbor, current);
			gScore.put(neighbor, tentativeGScore);
			fScore.put(neighbor, tentativeGScore + heuristic(neighbor, end));

			if (!openSet.contains(neighbor)) {
			openSet.add(neighbor);
			}
			}
			}
			}

			// 如果没有找到路径，不做不安全的连接
			return new ArrayList<>();
			}

			/**
			* 重构路径
			*/
			private static List<PathSegment> reconstructPath(Map<Point, Point> cameFrom, Point current) {
			List<Point> pathPoints = new ArrayList<>();
			while (current != null) {
			pathPoints.add(current);
			current = cameFrom.get(current);
			}
			Collections.reverse(pathPoints);

			List<PathSegment> path = new ArrayList<>();
			for (int i = 0; i < pathPoints.size() - 1; i++) {
			path.add(new PathSegment(pathPoints.get(i), pathPoints.get(i + 1), false));
			}
			return path;
			}

			/**
			* 启发函数
			*/
			private static double heuristic(Point a, Point b) {
			return distance(a, b);
			}

			/**
			* 优化路径
			*/
			private static List<PathSegment> optimizePath(List<PathSegment> path, double width) {
			if (path.size() <= 1) return path;

			List<PathSegment> optimized = new ArrayList<>();
			PathSegment current = path.get(0);

			for (int i = 1; i < path.size(); i++) {
			PathSegment next = path.get(i);

			// 检查是否可以合并当前线段和下一线段
			if (canMergeSegments(current, next, width)) {
			// 合并线段
			current = mergeSegments(current, next);
			} else {
			// 添加当前线段，开始新的合并
			optimized.add(current);
			current = next;
			}
			}

			optimized.add(current);

			// 平滑转角
			optimized = smoothCorners(optimized, width);

			return optimized;
			}

			/**
			* 检查是否可以合并两个线段
			*/
			private static boolean canMergeSegments(PathSegment a, PathSegment b, double width) {
			if (!a.isMowing \|\| !b.isMowing) return false;

			// 检查端点是否重合
			if (!a.end.equals(b.start) && !a.end.equals(b.end)) return false;

			// 检查方向是否一致
			Point dir1 = new Point(a.end.x - a.start.x, a.end.y - a.start.y);
			Point dir2;
			if (a.end.equals(b.start)) {
			dir2 = new Point(b.end.x - b.start.x, b.end.y - b.start.y);
			} else {
			dir2 = new Point(b.start.x - b.end.x, b.start.y - b.end.y);
			}

			double angle = angleBetween(dir1, dir2);
			return angle < Math.toRadians(10); // 角度小于10度可以合并
			}

			/**
			* 合并两个线段
			*/
			private static PathSegment mergeSegments(PathSegment a, PathSegment b) {
			Point newEnd = a.end.equals(b.start) ? b.end : b.start;
			return new PathSegment(a.start, newEnd, true);
			}

			/**
			* 平滑转角
			*/
			private static List<PathSegment> smoothCorners(List<PathSegment> path, double width) {
			if (path.size() < 3) return path;

			List<PathSegment> smoothed = new ArrayList<>();
			smoothed.add(path.get(0));

			for (int i = 1; i < path.size() - 1; i++) {
			PathSegment prev = path.get(i - 1);
			PathSegment curr = path.get(i);
			PathSegment next = path.get(i + 1);

			if (!prev.isMowing \|\| !curr.isMowing \|\| !next.isMowing) {
			smoothed.add(curr);
			// 2. 移除在障碍物内部的线段
			List<PathSegment> remainingSegments = new ArrayList<>();
			for (PathSegment seg : originalSegments) {
			if (!seg.isMowing) {
			// 空走段直接保留
			remainingSegments.add(seg);
			continue;
			}

			// 计算转角
			Point inVec = new Point(curr.start.x - prev.end.x, curr.start.y - prev.end.y);
			Point outVec = new Point(next.start.x - curr.end.x, next.start.y - curr.end.y);
			// 将割草段与所有障碍物进行裁剪
			List<PathSegment> clippedSegments = new ArrayList<>();
			clippedSegments.add(seg);

			double angle = angleBetween(inVec, outVec);
			for (Obstacle obs : obstacles) {
			List<PathSegment> newSegments = new ArrayList<>();
			for (PathSegment s : clippedSegments) {
			newSegments.addAll(clipSegmentWithObstacle(s, obs));
			}
			clippedSegments = newSegments;
			}

			if (angle < CORNER_THRESHOLD) {
			// 小角度，可以直接连接
			PathSegment direct = new PathSegment(prev.end, next.start, true);
			smoothed.remove(smoothed.size() - 1); // 移除上一个线段
			smoothed.add(direct);
			i++; // 跳过下一个线段
			remainingSegments.addAll(clippedSegments);
			}

			// 3. 重新连接路径段（弓字形连接）
			return reconnectSegments(remainingSegments);
			}

			/**
			* 将线段与障碍物进行裁剪
			* 返回不在障碍物内部的子线段
			*/
			private static List<PathSegment> clipSegmentWithObstacle(PathSegment segment, Obstacle obstacle) {
			List<PathSegment> result = new ArrayList<>();

			// 检查线段是否完全在障碍物外部
			boolean startInside = obstacle.contains(segment.start);
			boolean endInside = obstacle.contains(segment.end);

			if (!startInside && !endInside) {
			// 线段两端都在外部，检查是否穿过障碍物
			List<Point> intersections = obstacle.getIntersections(segment);
			if (intersections.isEmpty()) {
			// 完全在外部
			result.add(segment);
			} else {
			smoothed.add(curr);
			}
			}

			if (path.size() > 1) {
			smoothed.add(path.get(path.size() - 1));
			}

			return smoothed;
			}

			// ==================== 几何计算工具 ====================

			/**
			* 多边形偏移算法
			*/
			private static List<Point> offsetPolygon(List<Point> polygon, double d) {
			// 基于“偏移边直线交点”的较稳健实现。约定polygon为CCW，左法向量为外侧。
			if (polygon == null \|\| polygon.size() < 3) return new ArrayList<>();
			List<Point> poly = new ArrayList<>(polygon);
			makeCCW(poly);
			int n = poly.size();
			List<Point> out = new ArrayList<>(n);

			for (int i = 0; i < n; i++) {
			Point A = poly.get((i - 1 + n) % n);
			Point B = poly.get(i);
			Point C = poly.get((i + 1) % n);

			Point e1 = normalize(subtract(B, A));
			Point e2 = normalize(subtract(C, B));
			Point n1 = new Point(-e1.y, e1.x);
			Point n2 = new Point(-e2.y, e2.x);

			Point p1 = add(B, multiply(n1, d));
			Point p2 = add(B, multiply(n2, d));

			Point dir1 = e1;
			Point dir2 = e2;

			Point inter = intersectLines(p1, dir1, p2, dir2);
			if (inter == null) {
			// 平行或数值不稳定时退化
			Point avgN = add(n1, n2);
			if (magnitude(avgN) < EPS) avgN = n1;
			else avgN = normalize(avgN);
			inter = add(B, multiply(avgN, d));
			}
			out.add(inter);
			}
			return out;
			}

			// 计算两条参数直线的交点 p=p0+tv, q=q0+sw
			private static Point intersectLines(Point p0, Point v, Point q0, Point w) {
			double det = v.x * w.y - v.y * w.x;
			if (Math.abs(det) < EPS) return null;
			double t = ((q0.x - p0.x) * w.y - (q0.y - p0.y) * w.x) / det;
			return new Point(p0.x + t * v.x, p0.y + t * v.y);
			}

			/**
			* 计算最优扫描角度
			*/
			private static double calculateOptimalScanAngle(List<Point> polygon) {
			double bestAngle = 0;
			double minSpan = Double.MAX_VALUE;

			// 尝试多个角度
			for (int i = 0; i < 180; i += 5) {
			double angle = Math.toRadians(i);
			List<Point> rotated = rotatePolygon(polygon, angle);

			Bounds bounds = calculateBounds(rotated);
			double span = bounds.maxY - bounds.minY;

			if (span < minSpan) {
			minSpan = span;
			bestAngle = angle;
			}
			}

			return bestAngle;
			}

			/**
			* 获取水平线与多边形的交点
			*/
			private static List<Double> getHorizontalIntersections(List<Point> polygon, double y) {
			List<Double> intersections = new ArrayList<>();
			int n = polygon.size();

			for (int i = 0; i < n; i++) {
			Point p1 = polygon.get(i);
			Point p2 = polygon.get((i + 1) % n);

			// 检查边是否与水平线相交
			if ((p1.y <= y && p2.y >= y) \|\| (p1.y >= y && p2.y <= y)) {
			if (Math.abs(p2.y - p1.y) < EPS) {
			// 水平边，跳过
			continue;
			}
			// 穿过障碍物，分割线段
			intersections.sort(Comparator.comparingDouble(p ->
			distance(segment.start, p)));

			double t = (y - p1.y) / (p2.y - p1.y);
			if (t >= -EPS && t <= 1 + EPS) {
			double x = p1.x + t * (p2.x - p1.x);
			intersections.add(x);
			Point prevPoint = segment.start;
			for (Point inter : intersections) {
			result.add(new PathSegment(prevPoint, inter, true));
			prevPoint = inter;
			}
			result.add(new PathSegment(prevPoint, segment.end, true));

			// 移除在障碍物内部的段（奇数索引的段）
			List<PathSegment> filtered = new ArrayList<>();
			for (int i = 0; i < result.size(); i++) {
			PathSegment s = result.get(i);
			Point midPoint = new Point(
			(s.start.x + s.end.x) / 2,
			(s.start.y + s.end.y) / 2
			);
			if (!obstacle.contains(midPoint)) {
			filtered.add(s);
			}
			}
			return filtered;
			}
			} else if (startInside && endInside) {
			// 完全在内部，丢弃
			return result;
			} else {
			// 一端在内部，一端在外部
			Point insidePoint = startInside ? segment.start : segment.end;
			Point outsidePoint = startInside ? segment.end : segment.start;

			List<Point> intersections = obstacle.getIntersections(segment);
			if (!intersections.isEmpty()) {
			// 取离外部点最近的交点
			intersections.sort(Comparator.comparingDouble(p ->
			distance(outsidePoint, p)));
			Point inter = intersections.get(0);

			// 只保留外部部分
			if (startInside) {
			result.add(new PathSegment(inter, outsidePoint, true));
			} else {
			result.add(new PathSegment(outsidePoint, inter, true));
			}
			}
			}

			// 去重并排序
			intersections = intersections.stream()
			.distinct()
			.sorted()
			.collect(Collectors.toList());

			return intersections;
			return result;
			}

			/**
			* 判断直线是否安全
			* 重新连接路径段，形成连续弓字形路径
			*/
			private static boolean isLineSafe(Point p1, Point p2, List<Obstacle> obstacles, List<Point> workingArea) {
			// 必须完全在作业内缩边界内
			if (workingArea != null && !isSegmentInsidePolygon(p1, p2, workingArea)) {
			return false;
			}
			for (Obstacle obs : obstacles) {
			if (obs.doesSegmentIntersect(p1, p2)) {
			return false;
			}
			}
			return true;
			}

			// 判断线段是否位于多边形内部（不越界）
			private static boolean isSegmentInsidePolygon(Point a, Point b, List<Point> polygon) {
			if (polygon == null \|\| polygon.size() < 3) return true;
			// 中点在内
			Point mid = new Point((a.x + b.x) / 2.0, (a.y + b.y) / 2.0);
			if (!pointInPolygon(mid, polygon)) return false;
			// 不与边界相交（允许端点接触）
			int n = polygon.size();
			for (int i = 0; i < n; i++) {
			Point p1 = polygon.get(i);
			Point p2 = polygon.get((i + 1) % n);
			if (lineSegmentIntersection(a, b, p1, p2)) {
			// 忽略仅在端点处的小接触
			if (distance(a, p1) < EPS \|\| distance(a, p2) < EPS \|\| distance(b, p1) < EPS \|\| distance(b, p2) < EPS) {
			continue;
			private static List<PathSegment> reconnectSegments(List<PathSegment> segments) {
			if (segments.isEmpty()) return new ArrayList<>();

			List<PathSegment> reconnected = new ArrayList<>();
			Point currentPos = segments.get(0).start;

			for (PathSegment seg : segments) {
			if (seg.isMowing) {
			// 割草段：检查是否需要添加空走段
			if (distance(currentPos, seg.start) > 0.01) {
			reconnected.add(new PathSegment(currentPos, seg.start, false));
			}
			return false;
			reconnected.add(seg);
			currentPos = seg.end;
			} else {
			// 空走段直接添加
			reconnected.add(seg);
			currentPos = seg.end;
			}
			}
			return true;
			}

			private static boolean pointInPolygon(Point p, List<Point> poly) {
			boolean inside = false;
			for (int i = 0, j = poly.size() - 1; i < poly.size(); j = i++) {
			Point pi = poly.get(i), pj = poly.get(j);
			boolean intersect = ((pi.y > p.y) != (pj.y > p.y)) &&
			(p.x < (pj.x - pi.x) * (p.y - pi.y) / (pj.y - pi.y + EPS) + pi.x);
			if (intersect) inside = !inside;
			}
			return inside;
			}

			// ==================== 向量运算工具 ====================

			private static Point add(Point a, Point b) {
			return new Point(a.x + b.x, a.y + b.y);
			}

			private static Point subtract(Point a, Point b) {
			return new Point(a.x - b.x, a.y - b.y);
			}

			private static Point multiply(Point p, double scalar) {
			return new Point(p.x * scalar, p.y * scalar);
			}

			private static Point normalize(Point p) {
			double mag = magnitude(p);
			if (mag < EPS) return p;
			return new Point(p.x / mag, p.y / mag);
			}

			private static double magnitude(Point p) {
			return Math.sqrt(p.x * p.x + p.y * p.y);
			}

			private static double dot(Point a, Point b) {
			return a.x * b.x + a.y * b.y;
			}

			private static double angleBetween(Point a, Point b) {
			double dotProd = dot(a, b);
			double magA = magnitude(a);
			double magB = magnitude(b);

			if (magA < EPS \|\| magB < EPS) return 0;
			return reconnected;
			}

			/**
			* 生成原始扫描路径（无障碍物版本）
			*/
			private static List<PathSegment> generateGlobalScanPath(
			List<Point> polygon, double width, double angle, Point currentPos) {

			double cosAngle = dotProd / (magA * magB);
			cosAngle = Math.max(-1, Math.min(1, cosAngle));
			return Math.acos(cosAngle);
			}

			private static double distance(Point a, Point b) {
			return magnitude(subtract(a, b));
			}

			private static Point rotatePoint(Point p, double angle) {
			double cos = Math.cos(angle);
			double sin = Math.sin(angle);
			return new Point(p.x * cos - p.y * sin, p.x * sin + p.y * cos);
			}

			private static List<Point> rotatePolygon(List<Point> polygon, double angle) {
			return polygon.stream()
			.map(p -> rotatePoint(p, angle))
			.collect(Collectors.toList());
			}

			private static Bounds calculateBounds(List<Point> points) {
			double minX = Double.MAX_VALUE, maxX = -Double.MAX_VALUE;
			List<PathSegment> segments = new ArrayList<>();
			List<Point> rotatedPoly = new ArrayList<>();
			for (Point p : polygon) rotatedPoly.add(rotatePoint(p, -angle));

			double minY = Double.MAX_VALUE, maxY = -Double.MAX_VALUE;

			for (Point p : points) {
			minX = Math.min(minX, p.x);
			maxX = Math.max(maxX, p.x);
			for (Point p : rotatedPoly) {
			minY = Math.min(minY, p.y);
			maxY = Math.max(maxY, p.y);
			}

			return new Bounds(minX, maxX, minY, maxY);
			}

			private static void makeCCW(List<Point> polygon) {
			double area = 0;
			int n = polygon.size();

			for (int i = 0; i < n; i++) {
			Point p1 = polygon.get(i);
			Point p2 = polygon.get((i + 1) % n);
			area += (p2.x - p1.x) * (p2.y + p1.y);
			boolean leftToRight = true;
			for (double y = minY + width/2; y <= maxY - width/2; y += width) {
			List<Double> xIntersections = getXIntersections(rotatedPoly, y);
			if (xIntersections.size() < 2) continue;
			Collections.sort(xIntersections);

			List<PathSegment> lineSegmentsInRow = new ArrayList<>();
			for (int i = 0; i < xIntersections.size() - 1; i += 2) {
			Point pS = rotatePoint(new Point(xIntersections.get(i), y), angle);
			Point pE = rotatePoint(new Point(xIntersections.get(i + 1), y), angle);
			lineSegmentsInRow.add(new PathSegment(pS, pE, true));
			}

			if (!leftToRight) {
			Collections.reverse(lineSegmentsInRow);
			for (PathSegment s : lineSegmentsInRow) {
			Point temp = s.start;
			s.start = s.end;
			s.end = temp;
			}
			}

			for (PathSegment s : lineSegmentsInRow) {
			if (distance(currentPos, s.start) > 0.01) {
			segments.add(new PathSegment(currentPos, s.start, false));
			}
			segments.add(s);
			currentPos = s.end;
			}
			leftToRight = !leftToRight;
			}

			if (area > 0) {
			Collections.reverse(polygon);
			}
			return segments;
			}

			// ==================== 障碍物处理 ====================

			private static List<Obstacle> parseAndExpandObstacles(String obstaclesStr, double margin) {
			/**
			* 解析障碍物字符串
			* 格式："(x1,y1;x2,y2)(x1,y1;x2,y2;x3,y3)"
			*/
			private static List<Obstacle> parseObstacles(String obstaclesStr) {
			List<Obstacle> obstacles = new ArrayList<>();

			if (obstaclesStr == null \|\| obstaclesStr.trim().isEmpty()) {
			return obstacles;
			}

			// 解析障碍物字符串
			Pattern pattern = Pattern.compile("\\(([^)]+)\\)");
			Matcher matcher = pattern.matcher(obstaclesStr);
			String trimmed = obstaclesStr.trim();
			List<String> obstacleStrs = new ArrayList<>();

			while (matcher.find()) {
			String coords = matcher.group(1);
			List<Point> points = parseCoordinates(coords);
			// 分割每个障碍物（用括号分隔）
			int start = trimmed.indexOf('(');
			while (start != -1) {
			int end = trimmed.indexOf(')', start);
			if (end == -1) break;

			String obsStr = trimmed.substring(start + 1, end);
			obstacleStrs.add(obsStr);
			start = trimmed.indexOf('(', end);
			}

			// 解析每个障碍物
			for (String obsStr : obstacleStrs) {
			List<Point> points = new ArrayList<>();
			String[] pairs = obsStr.split(";");

			for (String pair : pairs) {
			String[] xy = pair.split(",");
			if (xy.length == 2) {
			points.add(new Point(
			Double.parseDouble(xy[0].trim()),
			Double.parseDouble(xy[1].trim())
			));
			}
			}

			if (points.size() == 2) {
			// 圆形障碍物
			// 圆形障碍物：第一个点为圆心，第二个点为圆上一点
			Point center = points.get(0);
			double radius = distance(center, points.get(1)) + margin;
			obstacles.add(new CircularObstacle(center, radius));
			} else if (points.size() >= 3) {
			Point onCircle = points.get(1);
			double radius = distance(center, onCircle);
			obstacles.add(new Obstacle(center, radius));
			} else if (points.size() > 2) {
			// 多边形障碍物
			makeCCW(points);
			List<Point> expanded = offsetPolygon(points, margin);
			obstacles.add(new PolygonalObstacle(expanded));
			obstacles.add(new Obstacle(points));
			}
			}

			return obstacles;
			}

			private static List<Point> parseCoordinates(String str) {
			List<Point> points = new ArrayList<>();
			/**
			* 外扩障碍物（增加安全边距）
			*/
			private static List<Obstacle> expandObstacles(List<Obstacle> obstacles, double margin) {
			List<Obstacle> expanded = new ArrayList<>();

			if (str == null \|\| str.trim().isEmpty()) {
			return points;
			}

			String[] tokens = str.split(";");
			for (String token : tokens) {
			token = token.trim();
			if (token.isEmpty()) continue;

			String[] xy = token.split(",");
			if (xy.length == 2) {
			try {
			double x = Double.parseDouble(xy[0].trim());
			double y = Double.parseDouble(xy[1].trim());
			points.add(new Point(x, y));
			} catch (NumberFormatException e) {
			System.err.println("无效坐标: " + token);
			}
			for (Obstacle obs : obstacles) {
			if (obs.isCircle()) {
			// 圆形：半径增加安全边距
			expanded.add(new Obstacle(obs.center, obs.radius + margin));
			} else {
			// 多边形：向外偏移（与边界内缩方向相反）
			List<Point> expandedPoints = getOutsetPolygon(obs.points, margin);
			expanded.add(new Obstacle(expandedPoints));
			}
			}

			return points;
			}

			// ==================== 内部类定义 ====================

			/**
			* 障碍物基类
			*/
			abstract static class Obstacle {
			abstract List<PathSegment> clipSegment(PathSegment seg);
			abstract boolean doesSegmentIntersect(Point p1, Point p2);
			abstract boolean containsPoint(Point p);
			abstract List<Point> getKeyPoints();
			return expanded;
			}

			/**
			* 多边形障碍物
			* 多边形外扩（与内缩方向相反）
			*/
			static class PolygonalObstacle extends Obstacle {
			List<Point> vertices;
			private static List<Point> getOutsetPolygon(List<Point> points, double margin) {
			// 这里使用简化的外扩方法：沿法线向外移动
			List<Point> outset = new ArrayList<>();
			int n = points.size();

			PolygonalObstacle(List<Point> vertices) {
			this.vertices = vertices;
			}

			@Override
			List<PathSegment> clipSegment(PathSegment seg) {
			List<Double> tValues = new ArrayList<>();
			tValues.add(0.0);
			tValues.add(1.0);
			for (int i = 0; i < n; i++) {
			Point pPrev = points.get((i - 1 + n) % n);
			Point pCurr = points.get(i);
			Point pNext = points.get((i + 1) % n);

			// 收集所有交点
			for (int i = 0; i < vertices.size(); i++) {
			Point p1 = vertices.get(i);
			Point p2 = vertices.get((i + 1) % vertices.size());

			Double t = lineIntersection(seg.start, seg.end, p1, p2);
			if (t != null) {
			tValues.add(t);
			}
			// 计算两个边的向量
			double v1x = pCurr.x - pPrev.x, v1y = pCurr.y - pPrev.y;
			double v2x = pNext.x - pCurr.x, v2y = pNext.y - pCurr.y;

			// 计算法线（确保向外）
			double nx1 = -v1y, ny1 = v1x;
			double nx2 = -v2y, ny2 = v2x;

			// 归一化
			double len1 = Math.hypot(nx1, ny1);
			double len2 = Math.hypot(nx2, ny2);
			if (len1 > 1e-6) { nx1 /= len1; ny1 /= len1; }
			if (len2 > 1e-6) { nx2 /= len2; ny2 /= len2; }

			// 计算平均法线方向
			double nx = (nx1 + nx2) / 2;
			double ny = (ny1 + ny2) / 2;
			double len = Math.hypot(nx, ny);
			if (len > 1e-6) {
			nx /= len;
			ny /= len;
			}

			Collections.sort(tValues);
			List<PathSegment> result = new ArrayList<>();

			// 生成不在障碍物内部的线段段
			for (int i = 0; i < tValues.size() - 1; i++) {
			double t1 = tValues.get(i);
			double t2 = tValues.get(i + 1);
			double tMid = (t1 + t2) / 2;

			Point midPoint = interpolate(seg.start, seg.end, tMid);
			if (!containsPoint(midPoint)) {
			Point start = interpolate(seg.start, seg.end, t1);
			Point end = interpolate(seg.start, seg.end, t2);
			result.add(new PathSegment(start, end, seg.isMowing));
			}
			}

			return result;
			// 向外移动
			outset.add(new Point(
			pCurr.x + nx * margin,
			pCurr.y + ny * margin
			));
			}

			@Override
			boolean doesSegmentIntersect(Point p1, Point p2) {
			for (int i = 0; i < vertices.size(); i++) {
			Point v1 = vertices.get(i);
			Point v2 = vertices.get((i + 1) % vertices.size());

			if (lineSegmentIntersection(p1, p2, v1, v2)) {
			return true;
			}
			}
			return false;
			}

			@Override
			boolean containsPoint(Point p) {
			int crossings = 0;

			for (int i = 0; i < vertices.size(); i++) {
			Point v1 = vertices.get(i);
			Point v2 = vertices.get((i + 1) % vertices.size());

			if (((v1.y <= p.y && p.y < v2.y) \|\| (v2.y <= p.y && p.y < v1.y)) &&
			(p.x < (v2.x - v1.x) * (p.y - v1.y) / (v2.y - v1.y) + v1.x)) {
			crossings++;
			}
			}

			return (crossings % 2) == 1;
			}

			@Override
			List<Point> getKeyPoints() {
			return new ArrayList<>(vertices);
			}
			return outset;
			}

			/**
			* 圆形障碍物
			* 障碍物类
			*/
			static class CircularObstacle extends Obstacle {
			Point center;
			double radius;
			private static class Obstacle {
			List<Point> points; // 多边形顶点（对圆形为空）
			Point center; // 圆心（仅对圆形有效）
			double radius; // 半径（仅对圆形有效）
			boolean isCircle;

			CircularObstacle(Point center, double radius) {
			this.center = center;
			// 多边形构造函数
			Obstacle(List<Point> points) {
			this.points = new ArrayList<>(points);
			this.isCircle = false;
			ensureCounterClockwise(this.points); // 确保顺时针（对障碍物是内部区域）
			}

			// 圆形构造函数
			Obstacle(Point center, double radius) {
			this.center = new Point(center.x, center.y);
			this.radius = radius;
			this.isCircle = true;
			this.points = new ArrayList<>();
			}

			@Override
			List<PathSegment> clipSegment(PathSegment seg) {
			double dx = seg.end.x - seg.start.x;
			double dy = seg.end.y - seg.start.y;
			double fx = seg.start.x - center.x;
			double fy = seg.start.y - center.y;

			double a = dx * dx + dy * dy;
			double b = 2 * (fx * dx + fy * dy);
			double c = fx * fx + fy * fy - radius * radius;

			List<Double> tValues = new ArrayList<>();
			tValues.add(0.0);
			tValues.add(1.0);

			double discriminant = b * b - 4 * a * c;
			if (discriminant > 0) {
			double sqrtDisc = Math.sqrt(discriminant);
			double t1 = (-b - sqrtDisc) / (2 * a);
			double t2 = (-b + sqrtDisc) / (2 * a);

			if (t1 > EPS && t1 < 1 - EPS) tValues.add(t1);
			if (t2 > EPS && t2 < 1 - EPS) tValues.add(t2);
			// 判断点是否在障碍物内部
			boolean contains(Point p) {
			if (isCircle) {
			return distance(p, center) <= radius;
			} else {
			return isPointInPolygon(p, points);
			}
			}

			// 获取线段与障碍物的交点
			List<Point> getIntersections(PathSegment segment) {
			List<Point> intersections = new ArrayList<>();

			Collections.sort(tValues);
			List<PathSegment> result = new ArrayList<>();

			for (int i = 0; i < tValues.size() - 1; i++) {
			double t1 = tValues.get(i);
			double t2 = tValues.get(i + 1);
			double tMid = (t1 + t2) / 2;
			if (isCircle) {
			// 线段与圆的交点
			double dx = segment.end.x - segment.start.x;
			double dy = segment.end.y - segment.start.y;
			double a = dx * dx + dy * dy;
			double b = 2 * (dx * (segment.start.x - center.x) +
			dy * (segment.start.y - center.y));
			double c = (segment.start.x - center.x) * (segment.start.x - center.x) +
			(segment.start.y - center.y) * (segment.start.y - center.y) -
			radius * radius;

			Point midPoint = interpolate(seg.start, seg.end, tMid);
			if (!containsPoint(midPoint)) {
			Point start = interpolate(seg.start, seg.end, t1);
			Point end = interpolate(seg.start, seg.end, t2);
			result.add(new PathSegment(start, end, seg.isMowing));
			double discriminant = b * b - 4 * a * c;
			if (discriminant >= 0) {
			discriminant = Math.sqrt(discriminant);
			for (int sign = -1; sign <= 1; sign += 2) {
			double t = (-b + sign * discriminant) / (2 * a);
			if (t >= 0 && t <= 1) {
			intersections.add(new Point(
			segment.start.x + t * dx,
			segment.start.y + t * dy
			));
			}
			}
			}
			} else {
			// 线段与多边形的交点
			for (int i = 0; i < points.size(); i++) {
			Point p1 = points.get(i);
			Point p2 = points.get((i + 1) % points.size());

			Point inter = getLineIntersection(
			segment.start, segment.end, p1, p2);
			if (inter != null) {
			intersections.add(inter);
			}
			}
			}

			return result;
			return intersections;
			}

			@Override
			boolean doesSegmentIntersect(Point p1, Point p2) {
			Point closest = closestPointOnSegment(center, p1, p2);
			// 将与圆的相切也视为相交，避免路径擦边
			return distance(center, closest) <= radius + EPS;
			boolean isCircle() {
			return isCircle;
			}

			@Override
			boolean containsPoint(Point p) {
			return distance(center, p) < radius - EPS;
			}

			@Override
			List<Point> getKeyPoints() {
			List<Point> points = new ArrayList<>();
			int numPoints = 8; // 八边形近似
			}

			/**
			* 判断点是否在多边形内部（射线法）
			*/
			private static boolean isPointInPolygon(Point p, List<Point> polygon) {
			boolean inside = false;
			for (int i = 0, j = polygon.size() - 1; i < polygon.size(); j = i++) {
			Point pi = polygon.get(i);
			Point pj = polygon.get(j);

			for (int i = 0; i < numPoints; i++) {
			double angle = 2 * Math.PI * i / numPoints;
			points.add(new Point(
			center.x + radius * Math.cos(angle),
			center.y + radius * Math.sin(angle)
			));
			if (((pi.y > p.y) != (pj.y > p.y)) &&
			(p.x < (pj.x - pi.x) * (p.y - pi.y) / (pj.y - pi.y) + pi.x)) {
			inside = !inside;
			}

			return points;
			}
			return inside;
			}

			/**
			* 路径段
			* 计算两条线段的交点
			*/
			public static class PathSegment {
			public Point start, end;
			public boolean isMowing;
			private static Point getLineIntersection(Point p1, Point p2, Point p3, Point p4) {
			double denom = (p1.x - p2.x) * (p3.y - p4.y) - (p1.y - p2.y) * (p3.x - p4.x);
			if (Math.abs(denom) < 1e-6) return null; // 平行

			public PathSegment(Point start, Point end, boolean isMowing) {
			this.start = start;
			this.end = end;
			this.isMowing = isMowing;
			double t = ((p1.x - p3.x) * (p3.y - p4.y) - (p1.y - p3.y) * (p3.x - p4.x)) / denom;
			double u = -((p1.x - p2.x) * (p1.y - p3.y) - (p1.y - p2.y) * (p1.x - p3.x)) / denom;

			if (t >= 0 && t <= 1 && u >= 0 && u <= 1) {
			return new Point(
			p1.x + t * (p2.x - p1.x),
			p1.y + t * (p2.y - p1.y)
			);
			}

			@Override
			public String toString() {
			return String.format("%s -> %s [%s]", start, end, isMowing ? "MOW" : "MOVE");
			}
			}

			/**
			* 点类
			*/
			public static class Point {
			public double x, y;

			public Point(double x, double y) {
			this.x = x;
			this.y = y;
			}

			@Override
			public boolean equals(Object obj) {
			if (this == obj) return true;
			if (!(obj instanceof Point)) return false;
			Point other = (Point) obj;
			return Math.abs(x - other.x) < EPS && Math.abs(y - other.y) < EPS;
			}

			@Override
			public int hashCode() {
			return Double.hashCode(x) * 31 + Double.hashCode(y);
			}

			@Override
			public String toString() {
			return String.format("(%.2f, %.2f)", x, y);
			}
			}

			/**
			* 边界框
			*/
			private static class Bounds {
			double minX, maxX, minY, maxY;

			Bounds(double minX, double maxX, double minY, double maxY) {
			this.minX = minX;
			this.maxX = maxX;
			this.minY = minY;
			this.maxY = maxY;
			}
			}

			// ==================== 几何工具函数 ====================

			private static Double lineIntersection(Point a1, Point a2, Point b1, Point b2) {
			double det = (a2.x - a1.x) * (b2.y - b1.y) - (a2.y - a1.y) * (b2.x - b1.x);

			if (Math.abs(det) < EPS) return null;

			double t = ((b1.x - a1.x) * (b2.y - b1.y) - (b1.y - a1.y) * (b2.x - b1.x)) / det;
			double u = ((a1.x - b1.x) * (a2.y - a1.y) - (a1.y - b1.y) * (a2.x - a1.x)) / (-det);

			if (t >= -EPS && t <= 1 + EPS && u >= -EPS && u <= 1 + EPS) {
			return Math.max(0, Math.min(1, t));
			}

			return null;
			}

			private static boolean lineSegmentIntersection(Point a1, Point a2, Point b1, Point b2) {
			Double t = lineIntersection(a1, a2, b1, b2);
			return t != null;
			/**
			* 计算两点距离
			*/
			private static double distance(Point p1, Point p2) {
			return Math.hypot(p1.x - p2.x, p1.y - p2.y);
			}

			private static Point interpolate(Point a, Point b, double t) {
			return new Point(a.x + (b.x - a.x) * t, a.y + (b.y - a.y) * t);
			// ============ 以下是从A代码复用的方法 ============

			private static Point getFirstScanPoint(List<Point> polygon, double width, double angle) {
			List<Point> rotatedPoly = new ArrayList<>();
			for (Point p : polygon) rotatedPoly.add(rotatePoint(p, -angle));
			double minY = Double.MAX_VALUE;
			for (Point p : rotatedPoly) minY = Math.min(minY, p.y);

			double firstY = minY + width/2;
			List<Double> xInter = getXIntersections(rotatedPoly, firstY);
			if (xInter.isEmpty()) return polygon.get(0);
			Collections.sort(xInter);
			return rotatePoint(new Point(xInter.get(0), firstY), angle);
			}

			private static Point closestPointOnSegment(Point p, Point a, Point b) {
			double ax = b.x - a.x;
			double ay = b.y - a.y;
			double bx = p.x - a.x;
			double by = p.y - a.y;

			double dot = ax * bx + ay * by;
			double lenSq = ax * ax + ay * ay;

			double t = (lenSq > EPS) ? Math.max(0, Math.min(1, dot / lenSq)) : 0;

			return new Point(a.x + t * ax, a.y + t * ay);
			}

			}
			private static List<Point> alignBoundaryStart(List<Point> boundary, Point targetStart) {
			int bestIdx = 0;
			double minDist = Double.MAX_VALUE;
			for (int i = 0; i < boundary.size(); i++) {
			double d = Math.hypot(boundary.get(i).x - targetStart.x, boundary.get(i).y - targetStart.y);
			if (d < minDist) { minDist = d; bestIdx = i; }
			}
			List<Point> aligned = new ArrayList<>();
			for (int i = 0; i < boundary.size(); i++) {
			aligned.add(boundary.get((bestIdx + i) % boundary.size()));
			}
			return aligned;
			}

			private static List<Double> getXIntersections(List<Point> rotatedPoly, double y) {
			List<Double> xIntersections = new ArrayList<>();
			for (int i = 0; i < rotatedPoly.size(); i++) {
			Point p1 = rotatedPoly.get(i);
			Point p2 = rotatedPoly.get((i + 1) % rotatedPoly.size());
			if ((p1.y <= y && p2.y > y) \|\| (p2.y <= y && p1.y > y)) {
			double x = p1.x + (y - p1.y) * (p2.x - p1.x) / (p2.y - p1.y);
			xIntersections.add(x);
			}
			}
			return xIntersections;
			}

			private static double findOptimalAngle(List<Point> polygon) {
			double bestAngle = 0;
			double minHeight = Double.MAX_VALUE;
			for (int i = 0; i < polygon.size(); i++) {
			Point p1 = polygon.get(i), p2 = polygon.get((i + 1) % polygon.size());
			double angle = Math.atan2(p2.y - p1.y, p2.x - p1.x);
			double h = calculateHeightAtAngle(polygon, angle);
			if (h < minHeight) { minHeight = h; bestAngle = angle; }
			}
			return bestAngle;
			}

			private static double calculateHeightAtAngle(List<Point> poly, double angle) {
			double minY = Double.MAX_VALUE, maxY = -Double.MAX_VALUE;
			for (Point p : poly) {
			Point rp = rotatePoint(p, -angle);
			minY = Math.min(minY, rp.y); maxY = Math.max(maxY, rp.y);
			}
			return maxY - minY;
			}

			private static List<Point> getInsetPolygon(List<Point> points, double margin) {
			List<Point> result = new ArrayList<>();
			int n = points.size();
			for (int i = 0; i < n; i++) {
			Point pPrev = points.get((i - 1 + n) % n);
			Point pCurr = points.get(i);
			Point pNext = points.get((i + 1) % n);

			double d1x = pCurr.x - pPrev.x, d1y = pCurr.y - pPrev.y;
			double l1 = Math.hypot(d1x, d1y);
			double d2x = pNext.x - pCurr.x, d2y = pNext.y - pCurr.y;
			double l2 = Math.hypot(d2x, d2y);

			if (l1 < 1e-6 \|\| l2 < 1e-6) continue;

			double n1x = -d1y / l1, n1y = d1x / l1;
			double n2x = -d2y / l2, n2y = d2x / l2;

			double bisectorX = n1x + n2x, bisectorY = n1y + n2y;
			double bLen = Math.hypot(bisectorX, bisectorY);
			if (bLen < 1e-6) { bisectorX = n1x; bisectorY = n1y; }
			else { bisectorX /= bLen; bisectorY /= bLen; }

			double cosHalfAngle = n1x * bisectorX + n1y * bisectorY;
			double dist = margin / Math.max(cosHalfAngle, 0.1);

			dist = Math.min(dist, margin * 5);

			result.add(new Point(pCurr.x + bisectorX * dist, pCurr.y + bisectorY * dist));
			}
			return result;
			}

			private static Point rotatePoint(Point p, double angle) {
			double cos = Math.cos(angle), sin = Math.sin(angle);
			return new Point(p.x * cos - p.y * sin, p.x * sin + p.y * cos);
			}

			private static void ensureCounterClockwise(List<Point> points) {
			double sum = 0;
			for (int i = 0; i < points.size(); i++) {
			Point p1 = points.get(i), p2 = points.get((i + 1) % points.size());
			sum += (p2.x - p1.x) * (p2.y + p1.y);
			}
			if (sum > 0) Collections.reverse(points);
			}

			private static List<Point> parseCoordinates(String coordinates) {
			List<Point> points = new ArrayList<>();
			String[] pairs = coordinates.split(";");
			for (String pair : pairs) {
			String[] xy = pair.split(",");
			if (xy.length == 2) points.add(new Point(Double.parseDouble(xy[0]), Double.parseDouble(xy[1])));
			}
			if (points.size() > 1 && points.get(0).equals(points.get(points.size()-1))) points.remove(points.size()-1);
			return points;
			}

			public static class Point {
			public double x, y;
			public Point(double x, double y) { this.x = x; this.y = y; }
			@Override
			public boolean equals(Object o) {
			if (!(o instanceof Point)) return false;
			Point p = (Point) o;
			return Math.abs(x - p.x) < 1e-4 && Math.abs(y - p.y) < 1e-4;
			}
			}

			public static class PathSegment {
			public Point start, end;
			public boolean isMowing;
			public PathSegment(Point s, Point e, boolean m) {
			this.start = s;
			this.end = e;
			this.isMowing = m;
			}
			}
			}