//2015.11.23 #include <iostream> #include <vector> #include <stack> #include "Defines.h" #include "OneSeg.h" //定义点 typedef struct _MyPoint { bool flag; double x; double y; _MyPoint(double _x = 0.0, double _y = 0.0, bool _flag = false) { x = _x; y = _y; flag = _flag; } }MyPoint; double CalcAngle(MyPoint first, MyPoint cen, MyPoint second) { double dx1, dx2, dy1, dy2; double angle; dx1 = first.x - cen.x; dy1 = first.y - cen.y; dx2 = second.x - cen.x; dy2 = second.y - cen.y; double c = (double)sqrt(dx1 * dx1 + dy1 * dy1) * (double)sqrt(dx2 * dx2 + dy2 * dy2); if (c == 0) return -1; angle = (double)acos((dx1 * dx2 + dy1 * dy2) / c); return angle / PAI * 180; } /* cp 在此是四个元素的数组: cp[0] 为起点,或上图中的 P0 cp[1] 为第一控制点,或上图中的 P1 cp[2] 为第二控制点,或上图中的 P2 cp[3] 为结束点,或上图中的 P3 t 为参数值,0 <= t <= 1 */ MyPoint PointOnCubicBezier(MyPoint* cp, double t) { double ax, bx, cx; double ay, by, cy; double tSquared, tCubed; MyPoint result; /* 计算多项式系数 */ cx = 3.0 * (cp[1].x - cp[0].x); bx = 3.0 * (cp[2].x - cp[1].x) - cx; ax = cp[3].x - cp[0].x - cx - bx; cy = 3.0 * (cp[1].y - cp[0].y); by = 3.0 * (cp[2].y - cp[1].y) - cy; ay = cp[3].y - cp[0].y - cy - by; /* 计算t位置的点值 */ tSquared = t * t; tCubed = tSquared * t; result.x = (ax * tCubed) + (bx * tSquared) + (cx * t) + cp[0].x; result.y = (ay * tCubed) + (by * tSquared) + (cy * t) + cp[0].y; return result; } /* ComputeBezier 以控制点 cp 所产生的曲线点,填入 MyPoint 结构数组。 调用方必须分配足够的空间以供输出,<sizeof(MyPoint) numberOfPoints> */ void ComputeBezier( MyPoint* cp, int numberOfPoints, MyPoint* curve ) { double dt; int i; dt = 1.0 / ( numberOfPoints - 1 ); for( i = 0; i < numberOfPoints; i++) curve[i] = PointOnCubicBezier( cp, i*dt ); } int FindSplit(std::vector<MyPoint>& V, int& i, int& j, int* f, double* dist) { if (i + 1 > j) { return -1; } *f = i + 1; COneSeg os(V[i].x, V[i].y, V[j].x, V[j].y); *dist = os.GapFromPoint(cv::Point2d(V[*f].x, V[*f].y)); for (int m = *f + 1; m < j; ++m) { double dTmpGap = os.GapFromPoint(cv::Point2d(V[m].x, V[m].y)); if (dTmpGap > *dist) { *dist = dTmpGap; *f = m; } } return 0; } int DouglasPeucker(std::vector<MyPoint>& V, int &i, int &j, double e) { if (V.size() <= 2) { //不需要处理 return -1; } double dist = 9999; int f = 0; //最大距离的点的序号 std::stack<int> tempVertex; //STL实现的栈 tempVertex.push(j); do { //循环i和j之间距离直线ij最大的点 FindSplit(V, i, j, &f, &dist); if (dist > e) //大于阈值 { V[f].flag = true; j = f; //更新B值 tempVertex.push(f); //记录最大距离点,放入栈中存储 continue; } else { if (!tempVertex.empty() && j != tempVertex.top()) //判断后一点是否和当前栈顶相等 { i = f; j = tempVertex.top(); continue; } else { if (j != V.size()) //判断最后一个点是否和当前线段的B点重合 { i = j; if (!tempVertex.empty()) { std::deque<int> cont = tempVertex._Get_container(); if (cont.size() > 1) //栈中至少还有两个点 { j = cont[cont.size() - 2]; } else if (cont.size() == 1) //栈中只有一个点 { j = cont[cont.size() - 1]; } tempVertex.pop(); continue; } } } } } while (!tempVertex.empty()); //保留首尾,去掉无用的点 for (int i = 1; i < V.size() - 1;) { if (V[i].flag == false) { V.erase(V.begin() + i); } else { i++; } } return int(tempVertex.size()); } int GetLineKeyPt(double* pX, double* pY, const int nNum, double** pOutX, double** pOutY, int *pOutNum, double dGap = 10.0) { std::vector<MyPoint> V; for (int m = 0; m < nNum; ++m) { V.push_back(MyPoint(pX[m], pY[m])); } int i = 0; int j = int(V.size() - 1); DouglasPeucker(V, i, j, dGap); //输出 *pOutNum = (int)V.size(); *pOutX = new double[*pOutNum]; *pOutY = new double[*pOutNum]; for (int i = 0; i < *pOutNum; ++i) { (*pOutX)[i] = V[i].x; (*pOutY)[i] = V[i].y; } V.clear(); return 0; } double Length(MyPoint p1, MyPoint p2) { return sqrt((p1.y - p2.y) * (p1.y - p2.y) + (p1.x - p2.x) * (p1.x - p2.x)); } double Slope(MyPoint p1, MyPoint p2) { if (std::fabs(p1.x - p2.x) <= 1e-7) { return DBL_MAX; } return (p1.y - p2.y) / (p1.x - p2.x); } double GapFromPoint(MyPoint p1, MyPoint p2, const MyPoint& pt ) { double k = Slope(p1, p2); if (k == DBL_MAX) { //垂直的时候直接返回差值 return fabs(p1.x - pt.x); } double b = p1.y - k * p1.x; return fabs(k * pt.x - pt.y + b) / sqrt( 1 + k * k); } bool IsPointInHalfLine(MyPoint p1, MyPoint p2, const MyPoint& pt, const double dDiff /*= 1.0*/ ) { return GapFromPoint(p1, p2, pt) <= dDiff; } MyPoint GetCenter(MyPoint p1, MyPoint p2) { return MyPoint((p1.x + p2.x) / 2, (p1.y + p2.y) / 2); } bool GetPointInSeg(MyPoint p1, MyPoint p2, MyPoint& pRes, const double dGap /*= 10*/ ) { if (Length(p1, p2) < dGap) { return false; } if (p1.y == p2.y) { if (p1.x < p2.x) { pRes = MyPoint(p2.x - dGap, p1.y); } else { pRes = MyPoint(p2.x + dGap, p1.y); } return true; } if (p1.x == p2.x) { if (p1.y < p2.y) { pRes = MyPoint(p1.x, p2.y - dGap); } else { pRes = MyPoint(p1.x, p2.y + dGap); } return true; } double dResX = p2.x - (p2.x - p1.x) * dGap / Length(p1, p2); double dResY = p1.y - (p1.y - p2.y)*(Length(p1, p2) - dGap)/Length(p1, p2); pRes = MyPoint(dResX, dResY); return true; } double TwoPointsGap(const double x1, const double y1, const double x2, const double y2) { return sqrt((y1 - y2) * (y1 - y2) + (x1 - x2) * (x1 - x2)); } double TwoPointsGap(const MyPoint& p1, const MyPoint& p2) { return TwoPointsGap(p1.x, p1.y, p2.x, p2.y); } int RemovePointByGap(double** pX, double** pY, int* nNum, const double& dGap = 1.0) { int nOldNum = *nNum; if (nOldNum < 3) { return -1; } //获取输入 std::vector<MyPoint> vPts(nOldNum); std::vector<MyPoint> vOut; for (int i = 0; i < nOldNum; ++i) { vPts[i] = MyPoint((*pX)[i], (*pY)[i]); } //取顺序的两个点 MyPoint ptStart, ptCurrent; ptStart = vPts[0]; ptCurrent = vPts[1]; vOut.push_back(ptStart); for (int i = 1; i < nOldNum - 1; ++i) { ptCurrent = vPts[i]; double dLength = Length(ptStart, ptCurrent); if (dLength > dGap) { vOut.push_back(ptCurrent); ptStart = ptCurrent; } } vOut.push_back(MyPoint((*pX)[nOldNum - 1], (*pY)[nOldNum - 1])); //释放原来的值 delete[] (*pX); delete[] (*pY); *pX = NULL; *pY = NULL; *nNum = (int)vOut.size(); *pX = new double[*nNum]; *pY = new double[*nNum]; for (int i = 0; i < *nNum; ++i) { (*pX)[i] = vOut[i].x; (*pY)[i] = vOut[i].y; } //注意这里不能delete,因为外部还会使用 return 0; } int CurveBrokenLine(std::vector<cv::Point>& vPts) { int nNum = vPts.size(); MyPoint* pt = new MyPoint[nNum]; for (int i = 0; i < nNum; ++i) { pt[i] = MyPoint(vPts[i].x, vPts[i].y); } for (int i = 0; i < nNum - 3; ++i) { ComputeBezier(pt, 4, pt); } for (int i = 0; i < nNum; ++i) { vPts[i] = cv::Point(pt[i].x, pt[i].y); } delete[] pt; pt = nullptr; return 0; } int SmoothBrokenLine(double* pX, double* pY, const int nNum) { if (nNum < 4) { return -1; } const int nBezierNum = 4; int nTime = nNum / 4; MyPoint* pPts = new MyPoint[nBezierNum]; MyPoint* pOut = new MyPoint[nBezierNum]; for (int i = 0; i < nTime; ++i) { for (int j = 0; j < nBezierNum; ++j) { pPts[j] = MyPoint(pX[i * 4 + j], pY[i * 4 + j]); } ComputeBezier(pPts, 4, pOut); for (int j = 0; j < nBezierNum; ++j) { pX[i * 4 + j] = pOut[j].x; pY[i * 4 + j] = pOut[j].y; } } //最后4个结果再次拟合 for (int j = 0; j < nBezierNum; ++j) { pPts[j] = MyPoint(pX[nNum - 4 + j], pY[nNum - 4 + j]); } ComputeBezier(pPts, 4, pOut); for (int j = 0; j < nBezierNum; ++j) { pX[nNum - 4 + j] = pOut[j].x; pY[nNum - 4 + j] = pOut[j].y; } delete[] pPts; delete[] pOut; pPts = NULL; pOut = NULL; return 0; }