Farmer John's hobby of conducting high-energy physics experiments on weekends has backfired, causing N wormholes (2 <= N <= 12, N even) to materialize on his farm, each located at a distinct point on the 2D map of his farm (the x,y coordinates are both integers).
According to his calculations, Farmer John knows that his wormholes will form N/2 connected pairs. For example, if wormholes A and B are connected as a pair, then any object entering wormhole A will exit wormhole B moving in the same direction, and any object entering wormhole B will similarly exit from wormhole A moving in the same direction. This can have rather unpleasant consequences.
For example, suppose there are two paired wormholes A at (1,1) and B at (3,1), and that Bessie the cow starts from position (2,1) moving in the +x direction. Bessie will enter wormhole B [at (3,1)], exit from A [at (1,1)], then enter B again, and so on, getting trapped in an infinite cycle!
| . . . . | A > B . Bessie will travel to B then + . . . . A then across to B again
Farmer John knows the exact location of each wormhole on his farm. He knows that Bessie the cow always walks in the +x direction, although he does not remember where Bessie is currently located.
Please help Farmer John count the number of distinct pairings of the wormholes such that Bessie could possibly get trapped in an infinite cycle if she starts from an unlucky position. FJ doesn't know which wormhole pairs with any other wormhole, so find all the possibilities.
Line 1: | The number of wormholes, N. |
Lines 2..1+N: | Each line contains two space-separated integers describing the (x,y) coordinates of a single wormhole. Each coordinate is in the range 0..1,000,000,000. |
4 0 0 1 0 1 1 0 1
There are 4 wormholes, forming the corners of a square.
Line 1: | The number of distinct pairings of wormholes such that Bessie could conceivably get stuck in a cycle walking from some starting point in the +x direction. |
2
If we number the wormholes 1..4 as we read them from the input, then if wormhole 1 pairs with wormhole 2 and wormhole 3 pairs with wormhole 4, Bessie can get stuck if she starts anywhere between (0,0) and (1,0) or between (0,1) and (1,1).
| . . . . 4 3 . . . Bessie will travel to B then 1-2-.-.-. A then across to B again
Similarly, with the same starting points, Bessie can get stuck in a cycle if the pairings are 1-3 and 2-4 (if Bessie enters WH#3 and comes out at WH#1, she then walks to WH#2 which transports here to WH#4 which directs her towards WH#3 again for a cycle).
Only the pairings 1-4 and 2-3 allow Bessie to walk in the +x direction from any point in the 2D plane with no danger of cycling.
数据很小,但是我不剪枝的枚举还是超时了。。。
发现官方题解真的很巧妙,每次枚举一对黑洞时,找第一个未配对的黑洞,这样绝对不会重复。
/*
ID: your_id_here
PROG: wormhole
LANG: C++
*/
#include
#include
#include
using namespace std;
int i,ans,n,nn,nnn,rig[12],par[12],cur,fac[6]={1,1,2,6,24,120};
bool vis[12];
struct Node {
int x,y;
bool operator < (const Node& a) const {
return y0)//特判是否在找第一对虫洞,如果是第一对虫洞并且都不是第一个虫洞则返回,防止重复计算(不要这个竟然超时...)
return;
if(par[i]==-1) {
for(j=i+1;ji防止i和j一对与j和i一对同时出现,变排列为组合
if(par[j]==-1) {
par[i]=j,par[j]=i;
dfs(num+1);
par[i]=par[j]=-1;
}
}
}
}
int main() {
freopen("wormhole.in","r",stdin);
freopen("wormhole.out","w",stdout);
while(1==scanf("%d",&n)) {
for(i=0;i>1,nnn=nn-1;
sort(p,p+n);
p[n].x=p[n].y=-1;//刚开始数组开小1个,导致越界,但是不提示,只说答案错误,狂交20次才发现...
for(i=0;i
#include
#include
using namespace std;
#define MAX_N 12
int N, X[MAX_N+1], Y[MAX_N+1];
int partner[MAX_N+1];
int next_on_right[MAX_N+1];
bool cycle_exists(void)
{
for (int start=1; start<=N; start++) {
// does there exist a cylce starting from start
int pos = start;
for (int count=0; count N) {
if (cycle_exists()) return 1;
else return 0;
}
// try pairing i with all possible other wormholes j
for (int j=i+1; j<=N; j++)
if (partner[j] == 0) {
// try pairing i & j, let recursion continue to
// generate the rest of the solution
partner[i] = j;
partner[j] = i;
total += solve();
partner[i] = partner[j] = 0;
}
return total;
}
int main(void)
{
ifstream fin("wormhole.in");
fin >> N;
for (int i=1; i<=N; i++) fin >> X[i] >> Y[i];
fin.close();
for (int i=1; i<=N; i++) // set next_on_right[i]...
for (int j=1; j<=N; j++)
if (X[j] > X[i] && Y[i] == Y[j]) // j right of i...
if (next_on_right[i] == 0 ||
X[j]-X[i] < X[next_on_right[i]]-X[i])
next_on_right[i] = j;
ofstream fout("wormhole.out");
fout << solve() << "\n";
fout.close();
return 0;
}