Frame Stacking
Time Limit: 2 Seconds Memory Limit: 65536 KB
Consider the following 5 picture frames placed on an 9 x 8 array.
Now place them on top of one another starting with 1 at the bottom and ending up with 5 on top. If any part of a frame covers another it hides that part of the frame below.
Viewing the stack of 5 frames we see the following.
In what order are the frames stacked from bottom to top? The answer is EDABC.
Your problem is to determine the order in which the frames are stacked from bottom to top given a picture of the stacked frames. Here are the rules:
1. The width of the frame is always exactly 1 character and the sides are never shorter than 3 characters.
2. It is possible to see at least one part of each of the four sides of a frame. A corner shows two sides.
3. The frames will be lettered with capital letters, and no two frames will be assigned the same letter.
INPUT DATA
Each input block contains the height, h (h<=30) on the first line and the width w (w<=30) on the second. A picture of the stacked frames is then given as h strings with w characters each.
Example input:
9
8
.CCC....
ECBCBB..
DCBCDB..
DCCC.B..
D.B.ABAA
D.BBBB.A
DDDDAD.A
E...AAAA
EEEEEE..
Your input may contain multiple blocks of the format described above, without any blank lines in between. All blocks in the input must be processed sequentially.
OUTPUT DATA
Write the solution to the standard output. Give the letters of the frames in the order they were stacked from bottom to top. If there are multiple possibilities for an ordering, list all such possibilities in alphabetical order, each one on a separate line. There will always be at least one legal ordering for each input block. List the output for all blocks in the input sequentially, without any blank lines (not even between blocks).
Example Output:
EDABC
//确定每个图形的4个顶点、然后就可以确定它被几个图覆盖了
//拓扑排序 至于输出所有情况的话、dfs搞定(不过要按字母序编号噢)
#include <iostream>
#include <stdio.h>
#include <queue>
#include <stack>
#include <set>
#include <vector>
#include <math.h>
#include <string.h>
#include <algorithm>
using namespace std;
vector <int> v[28];
struct ID
{
int x,y;
};
struct node
{
ID lt;
ID rb;
char c;
bool operator <(const node &b) const
{
return c<b.c;
}
}rc[28];
bool br[28];
bool bin[28][28];
int in[28];
int id[128];
char pt[28];
char map[33][33];
int k;
void dfs(int dp)
{
if(dp==k)
{
pt[dp]='\0';
printf("%s\n",pt);
return;
}
int l,i,j;
for(i=0;i<k;i++)
{
if(br[i]) continue;
if(in[i]==0)
{
pt[dp]=rc[i].c;
l=v[i].size();
for(j=0;j<l;j++)
in[v[i][j]]--;
br[i]=1;
dfs(dp+1);
br[i]=0;
for(j=0;j<l;j++)
in[v[i][j]]++;
}
}
}
int main()
{
int h,w;
int i,j;
while(scanf("%d %d",&h,&w)!=EOF)
{
getchar();
int tp=0;
memset(br,0,sizeof(br));
memset(in,0,sizeof(in));
memset(bin,0,sizeof(bin));
for(k=i=0;i<h;getchar(),i++)
for(j=0;j<w;j++)
{
scanf("%c",&map[i][j]);
if(map[i][j]=='.') continue;
if(!br[map[i][j]-'A'])
{
br[map[i][j]-'A']=1;
rc[k].c=map[i][j];
rc[k].lt.x=i;rc[k].lt.y=j;
rc[k].rb.x=i;rc[k].rb.y=j;
id[rc[k].c]=k;
k++;
}
else
{
tp=id[map[i][j]];
if(i<rc[tp].lt.x) rc[tp].lt.x=i;
if(i>rc[tp].rb.x) rc[tp].rb.x=i;
if(j<rc[tp].lt.y) rc[tp].lt.y=j;
if(j>rc[tp].rb.y) rc[tp].rb.y=j;
}
}
sort(rc,rc+k);
for(i=0;i<k;i++)
id[rc[i].c]=i;
int x,y;
for(i=0;i<k;i++)
{
x=rc[i].lt.x;
for(y=rc[i].lt.y;y<=rc[i].rb.y;y++)
if(map[x][y]!=rc[i].c)
{
tp=id[map[x][y]];
if(bin[i][tp]) continue;
v[i].push_back(tp);
in[tp]++;
bin[i][tp]=1;
}
x=rc[i].rb.x;
for(y=rc[i].lt.y;y<=rc[i].rb.y;y++)
if(map[x][y]!=rc[i].c)
{
tp=id[map[x][y]];
if(bin[i][tp]) continue;
v[i].push_back(tp);
in[tp]++;
bin[i][tp]=1;
}
y=rc[i].lt.y;
for(x=rc[i].lt.x;x<=rc[i].rb.x;x++)
if(map[x][y]!=rc[i].c)
{
tp=id[map[x][y]];
if(bin[i][tp]) continue;
v[i].push_back(tp);
in[tp]++;
bin[i][tp]=1;
}
y=rc[i].rb.y;
for(x=rc[i].lt.x;x<=rc[i].rb.x;x++)
if(map[x][y]!=rc[i].c)
{
tp=id[map[x][y]];
if(bin[i][tp]) continue;
v[i].push_back(tp);
in[tp]++;
bin[i][tp]=1;
}
}
memset(br,0,sizeof(br));
dfs(0);
for(i=0;i<k;i++) v[i].clear();
}
return 0;
}