/*

poj1873 The Fortified Forest 凸包+枚举 水题

用小树林的木头给小树林围一个围墙

每棵树都有价值

求消耗价值最低的做法，输出被砍伐的树的编号和剩余的木料

若砍伐价值相同，则取砍伐数小的方案。

*/

#include<stdio.h>

#include<math.h>

#include <algorithm>

#include <vector>

using namespace std;

const double eps = 1e-8;

struct point

{

	double x,y;

};

struct exinfo

{

	int v,l;

}info[20];

int n;

point dian[20],zhan[20];

//////////////////////////////////////////////////

point *mo_dian;

double mo_distance(point p1,point p2)

{

    return sqrt((p1.x-p2.x)*(p1.x-p2.x)+(p1.y-p2.y)*(p1.y-p2.y));

}

double mo_xmult(point p2,point p0,point p1)//p1在p2左返回负，在右边返回正

{

    return (p1.x-p0.x)*(p2.y-p0.y)-(p2.x-p0.x)*(p1.y-p0.y);

}

bool mo_ee(double x,double y)

{

	double ret=x-y;

	if(ret<0) ret=-ret;

	if(ret<eps) return 1;

	return 0;

}

bool mo_gg(double x,double y)  {   return x > y + eps;} // x > y

bool mo_ll(double x,double y)  {   return x < y - eps;} // x < y

bool mo_ge(double x,double y) {   return x > y - eps;} // x >= y

bool mo_le(double x,double y) {   return x < y + eps;}     // x <= y   

bool mo_cmp(point a,point b)   // 第一次排序

{

    if( mo_ee(a.y ,b.y ) )

        return mo_ll(a.x, b.x);

    return mo_ll(a.y,b.y);

}

bool mo_cmp1(point a,point b)  // 第二次排序

{

    double len = mo_xmult(b,mo_dian[0],a);

    if( mo_ee(len,0.0) )

        return mo_ll(mo_distance(mo_dian[0],a),mo_distance(mo_dian[0],b));

    return mo_gg(len,0.0);

}

int mo_graham(int n,point *dian,point *stk)

{

	int i,top=1;

	mo_dian=dian;

	sort(mo_dian,mo_dian+n,mo_cmp);

    sort(mo_dian+1,mo_dian+n,mo_cmp1);

	stk[0]=mo_dian[0];

    stk[1]=mo_dian[1];

	for(i=2;i<n;++i)

    {

        while(top>0&&mo_xmult(mo_dian[i],stk[top-1],stk[top])<=0) --top;

        stk[++top]=mo_dian[i];

    }

    return top+1;

}

////////

void getpoint(int tree,point *dian,point *work,vector<int> &cut,int &n_cut,int &n_sheng,int &cutv,int &cutl)

{

	cut.clear();

	cutv=0;

	cutl=n_sheng=n_cut=0;

	int i;

	for(i=0;i<n;++i)

	{

		if((1<<i)&tree)//cut

		{

			cut.push_back(i);

			n_cut++;

			cutv+=info[i].v;

			cutl+=info[i].l;

		}else

		{

			work[n_sheng++]=dian[i];

		}

	}

}

double zhou(point *dian,int n)

{

	int i;

	double ret=0;

	for(i=0;i<n;++i)

	{

		ret+=sqrt(

			(dian[(i+1)%n].x-dian[i].x)*(dian[(i+1)%n].x-dian[i].x)

			+(dian[(i+1)%n].y-dian[i].y)*(dian[(i+1)%n].y-dian[i].y)

			);

	}

	return ret;

}

int main()

{

	int i,ncase=1;

	while(scanf("%d",&n),n)

	{

		for(i=0;i<n;++i)

		{

			scanf("%lf%lf%d%d",&dian[i].x,&dian[i].y,&info[i].v,&info[i].l);

		}

		int maxofi=(1<<n)-1;

		int cutvalue=999999999;

		double l_sheng;

		int cutn;

		vector<int> cut;

		vector<int> tempcut;

		point work[20];

		for(i=0;i<maxofi;++i)

		{

			int tempcutn,shengyun;

			int tempcutv,cutl;

			int ret;

			double zhouchang;

			getpoint(i,dian,work,tempcut,tempcutn,shengyun,tempcutv,cutl);

			if(shengyun==1)

			{

				zhouchang=0;

			}else if(shengyun==2)

			{

				zhouchang=mo_distance(work[0],work[1])*2;

			}else

			{

				ret=mo_graham(shengyun,work,zhan);

				zhouchang=zhou(zhan,ret);

			}

			if(mo_ge(cutl,zhouchang))

			{

				if(tempcutv<cutvalue)

				{

					cutvalue=tempcutv;

					l_sheng=cutl-zhouchang;

					cut=tempcut;

					cutn=tempcutn;

				}else if(tempcutv==cutvalue&&tempcutn<cutn)

				{

					cutvalue=tempcutv;

					l_sheng=cutl-zhouchang;

					cut=tempcut;

					cutn=tempcutn;

				}

			}

		}

		if(ncase!=1) printf("\n");

		printf("Forest %d\n",ncase++);

		printf("Cut these trees:");

		int len=cut.size();

		for(i=0;i<len;++i)

		{

			printf(" %d",cut[i]+1);

		}

		printf("\n");

		printf("Extra wood: %.2lf\n",l_sheng);

	}

	return 0;

}