SGU 110. Dungeon 计算几何 难度:3
110. Dungeon
time limit per test: 0.25 sec.
memory limit per test: 4096 KB
The mission of space explorers found on planet M the vast dungeon. One of the dungeon halls is fill with the bright spheres. The explorers find out that the light rays reflect from the surface of the spheres according the ordinary law (the incidence angle is equal to the reflectance angle, the incidence ray, the reflected ray and the perpendicular to the sphere surface lay in the one plane). The ancient legend says that if the light ray will reflect from the spheres in the proper order, than the door to the room with very precious ancient knowledge will open. You are not to guess the right sequence; your task is much simpler. You are given the positions and the radii of the spheres, the place where the laser shot was made and the direction of light propagation. And you must find out the sequence in which the light will be reflected from the spheres.
Input
The first line of input contains the single integer n (1≤n≤50) - the amount of the spheres. The next n lines contain the coordinates and the radii of the spheres xi, yi, zi, ri (the integer numbers less or equal to 10000 by absolute value). The last line contains 6 real numbers - the coordinates of two points. The first one gives the coordinates of the place of laser shot, and the second gives the direction in which it was made (the second point is the point on the ray). The starting point of the ray lies strictly outside of any sphere.
Output
Your program must output the sequence of sphere numbers (spheres are numbers from 1 as they was given in input), from which the light ray was reflected. If the ray will reflect more the 10 times, than you must output first 10, then a space and the word 'etc.' (without quotes). Notice: if the light ray goes at a tangent to the sphere you must assume that the ray was reflected by the sphere.
Sample Input 1
1 0 0 2 1 0 0 0 0 0 1
Sample Output 1
1
Sample Input 2
2 0 0 2 1 0 0 -2 1 0 0 0 0 0 100
Sample Output 2
1 2 1 2 1 2 1 2 1 2 etc.
感想:计算几何远观的时候最难
思路:
1 判断射线反射交哪个球 如果使用点斜式会在0处出问题,题解使用了起点到球的距离相对射线反向的倍数,注意当这个倍数为0的时候,只要不是从这个球反射出去的也成立(也就是开始的时候光源就在这个球表面)
2 求反射后的光线向量,做一个以入射光线为平行边的一边,法线(圆心-入射点方向)为对角线做一个菱形,明显反射光线就是另外一边..的反向(!),所以反射光线就是入射向量-入射光线在法线上的投影*2,在这个地方弄成法线在入射光线WA一次
投影为单位法线*(入射和法线的点积)
最后注意一下,先判断有没有第11次反射再输出"etc."
#include<cstdio> #include <cstring> #include <cmath> using namespace std; class pnt{ public : double x,y,z; pnt():x(0),y(0),z(0){} pnt(double tx,double ty,double tz):x(tx),y(ty),z(tz){} pnt operator -(pnt besub){ pnt ans; ans.x=x-besub.x; ans.y=y-besub.y; ans.z=z-besub.z; return ans; } pnt operator +(pnt beadd){ pnt ans; ans.x=x+beadd.x; ans.y=y+beadd.y; ans.z=z+beadd.z; return ans; } pnt operator*(double bemul){ pnt ans; ans.x=x*bemul; ans.y=y*bemul; ans.z=z*bemul; return ans; } pnt operator/(double bediv){ pnt ans; ans.x=x/bediv; ans.y=y/bediv; ans.z=z/bediv; return ans; } double dot(pnt bepnt){ return x*bepnt.x+y*bepnt.y+z*bepnt.z; } double caldis(pnt other){ return sqrt((x-other.x)*(x-other.x)+(y-other.y)*(y-other.y)+(z-other.z)*(z-other.z)); } double len(){ return sqrt(x*x+y*y+z*z); } }; pnt ball[51],nowref,dir,start,normal; double ballr[51],mindis,nowdis; int n,nowball,nxtball; const double inf=1e18; int main(){ scanf("%d",&n); for(int i=1;i<=n;i++){ scanf("%lf%lf%lf%lf",&ball[i].x,&ball[i].y,&ball[i].z,ballr+i); } scanf("%lf%lf%lf%lf%lf%lf",&start.x,&start.y,&start.z,&dir.x,&dir.y,&dir.z); dir=dir-start; dir=dir/dir.len(); nowball=0; for(int time=0;time<11;time++){ nxtball=0; mindis=inf; for(int i=1;i<=n;i++){//开始使用了点法式,不行...换成比例简洁不出错 if(i==nowball)continue; double a=dir.x*dir.x+dir.y*dir.y+dir.z*dir.z; double b=2*(dir.x*(start.x-ball[i].x)+dir.y*(start.y-ball[i].y)+dir.z*(start.z-ball[i].z)); double c=(start.x-ball[i].x)*(start.x-ball[i].x)+(start.y-ball[i].y)*(start.y-ball[i].y)+(start.z-ball[i].z)*(start.z-ball[i].z)-ballr[i]*ballr[i]; double delta=b*b-4*a*c; if(delta<0)continue; nowdis=(-b+sqrt(delta))/2/a; if(nowdis>=0&&nowdis<mindis){//ATTENTION mindis=nowdis; nxtball=i; nowref=start+dir*(nowdis); } nowdis=(-b-sqrt(delta))/2/a; if(nowdis>=0&&nowdis<mindis){//ATTENTION mindis=nowdis; nxtball=i; nowref=start+dir*(nowdis); } } if(nxtball==0){break;} if(time)putchar(' '); if(time<10)printf("%d",nxtball); else {puts("etc.");break;} normal=ball[nxtball]-nowref; normal=normal/normal.len(); dir=dir-normal*(normal.dot(dir)*2.00); start=nowref; nowball=nxtball; } return 0; }