uva 1342 - That Nice Euler Circuit(欧拉定理)
题目链接:uva 1342 - That Nice Euler Circuit
欧拉定理:边数-点的个数+2=面数
#include <cstdio>
#include <cstring>
#include <cmath>
#include <algorithm>
using namespace std;
const double pi = 4 * atan(1);
const double eps = 1e-9;
inline int dcmp (double x) { if (fabs(x) < eps) return 0; else return x < 0 ? -1 : 1; }
inline double getDistance (double x, double y) { return sqrt(x * x + y * y); }
struct Point {
double x, y;
Point (double x = 0, double y = 0): x(x), y(y) {}
void read () { scanf("%lf%lf", &x, &y); }
void write () { printf("%lf %lf", x, y); }
bool operator == (const Point& u) const { return dcmp(x - u.x) == 0 && dcmp(y - u.y) == 0; }
bool operator != (const Point& u) const { return !(*this == u); }
bool operator < (const Point& u) const { return x < u.x || (x == u.x && y < u.y); }
bool operator > (const Point& u) const { return u < *this; }
bool operator <= (const Point& u) const { return *this < u || *this == u; }
bool operator >= (const Point& u) const { return *this > u || *this == u; }
Point operator + (const Point& u) { return Point(x + u.x, y + u.y); }
Point operator - (const Point& u) { return Point(x - u.x, y - u.y); }
Point operator * (const double u) { return Point(x * u, y * u); }
Point operator / (const double u) { return Point(x / u, y / u); }
};
typedef Point Vector;
struct Line {
double a, b, c;
Line (double a = 0, double b = 0, double c = 0): a(a), b(b), c(c) {}
};
namespace Punctual {
double getDistance (Point a, Point b) { double x=a.x-b.x, y=a.y-b.y; return sqrt(x*x + y*y); }
};
namespace Vectorial {
/* 点积: 两向量长度的乘积再乘上它们夹角的余弦, 夹角大于90度时点积为负 */
double getDot (Vector a, Vector b) { return a.x * b.x + a.y * b.y; }
/* 叉积: 叉积等于两向量组成的三角形有向面积的两倍, cross(v, w) = -cross(w, v) */
double getCross (Vector a, Vector b) { return a.x * b.y - a.y * b.x; }
double getLength (Vector a) { return sqrt(getDot(a, a)); }
double getAngle (Vector u) { return atan2(u.y, u.x); }
double getAngle (Vector a, Vector b) { return acos(getDot(a, b) / getLength(a) / getLength(b)); }
Vector rotate (Vector a, double rad) { return Vector(a.x*cos(rad)-a.y*sin(rad), a.x*sin(rad)+a.y*cos(rad)); }
/* 单位法线 */
Vector getNormal (Vector a) { double l = getLength(a); return Vector(-a.y/l, a.x/l); }
};
namespace Linear {
using namespace Vectorial;
Line getLine (double x1, double y1, double x2, double y2) { return Line(y2-y1, x1-x2, y1*(x2-x1)-x1*(y2-y1)); }
Line getLine (double a, double b, Point u) { return Line(a, -b, u.y * b - u.x * a); }
bool getIntersection (Line p, Line q, Point& o) {
if (fabs(p.a * q.b - q.a * p.b) < eps)
return false;
o.x = (q.c * p.b - p.c * q.b) / (p.a * q.b - q.a * p.b);
o.y = (q.c * p.a - p.c * q.a) / (p.b * q.a - q.b * p.a);
return true;
}
/* 直线pv和直线qw的交点 */
bool getIntersection (Point p, Vector v, Point q, Vector w, Point& o) {
if (dcmp(getCross(v, w)) == 0) return false;
Vector u = p - q;
double k = getCross(w, u) / getCross(v, w);
o = p + v * k;
return true;
}
/* 点p到直线ab的距离 */
double getDistanceToLine (Point p, Point a, Point b) { return fabs(getCross(b-a, p-a) / getLength(b-a)); }
double getDistanceToSegment (Point p, Point a, Point b) {
if (a == b) return getLength(p-a);
Vector v1 = b - a, v2 = p - a, v3 = p - b;
if (dcmp(getDot(v1, v2)) < 0) return getLength(v2);
else if (dcmp(getDot(v1, v3)) > 0) return getLength(v3);
else return fabs(getCross(v1, v2) / getLength(v1));
}
/* 点p在直线ab上的投影 */
Point getPointToLine (Point p, Point a, Point b) { Vector v = b-a; return a+v*(getDot(v, p-a) / getDot(v,v)); }
/* 判断线段是否存在交点 */
bool haveIntersection (Point a1, Point a2, Point b1, Point b2) {
double c1=getCross(a2-a1, b1-a1), c2=getCross(a2-a1, b2-a1), c3=getCross(b2-b1, a1-b1), c4=getCross(b2-b1,a2-b1);
return dcmp(c1)*dcmp(c2) < 0 && dcmp(c3)*dcmp(c4) < 0;
}
/* 判断点是否在线段上 */
bool onSegment (Point p, Point a, Point b) { return dcmp(getCross(a-p, b-p)) == 0 && dcmp(getDot(a-p, b-p)) < 0; }
}
namespace Triangular {
using namespace Vectorial;
double getAngle (double a, double b, double c) { return acos((a*a+b*b-c*c) / (2*a*b)); }
double getArea (double a, double b, double c) { double s =(a+b+c)/2; return sqrt(s*(s-a)*(s-b)*(s-c)); }
double getArea (double a, double h) { return a * h / 2; }
double getArea (Point a, Point b, Point c) { return fabs(getCross(b - a, c - a)) / 2; }
};
namespace Polygonal {
using namespace Vectorial;
double getArea (Point* p, int n) {
double ret = 0;
for (int i = 1; i < n-1; i++)
ret += getCross(p[i]-p[0], p[i+1]-p[0]);
return fabs(ret)/2;
}
};
using namespace Vectorial;
using namespace Linear;
const int maxn = 305;
Point P[maxn], V[maxn * maxn];
int main () {
int cas = 1, n;
while (scanf("%d", &n) == 1 && n) {
for (int i = 0; i < n; i++) {
P[i].read(), V[i] = P[i];
}
n--;
int e = n, c = n;
for (int i = 0; i < n; i++) {
for (int j = i + 1; j < n; j++) {
if (haveIntersection(P[i], P[i+1], P[j], P[j+1]))
getIntersection(P[i], P[i+1]-P[i], P[j], P[j+1] - P[j], V[c++]);
}
}
sort (V, V + c);
c = unique(V, V + c) - V;
for (int i = 0; i < c; i++) {
for (int j = 0; j < n; j++)
if (onSegment(V[i], P[j], P[j+1]))
e++;
}
printf("Case %d: There are %d pieces.\n", cas++, e + 2 - c);
}
return 0;
}