UVa 1592Database(map的妙用)
2017-06-21 15:25
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Peter studies the theory of relational databases. Table in the relational database consists of values that are arranged in rows and columns.
There are different normal forms that database may adhere to. Normal forms are designed to minimize the redundancy of data in the database. For example, a database table for a library might have a row for each book and columns for book name, book author, and
author's email.
If the same author wrote several books, then this representation is clearly redundant. To formally define this kind of redundancy Peter has introduced his own normal form. A table is in Peter's Normal Form (PNF) if and only if there is no pair of rows and a
pair of columns such that the values in the corresponding columns are the same for both rows.
The above table is clearly not in PNF, since values for 2rd and 3rd columns repeat in 2nd and 3rd rows.
However, if we introduce unique author identifier and split this table into two tables - one containing book name and author id, and the other containing book id, author name, and author email, then both resulting tables will be in PNF.
Given a table your task is to figure out whether it is in PNF or not.
Input
The first line of the input file contains two integer numbers n and m (1 <= n <= 10 000, 1 <= m <= 10), the number of rows and columns in the table. The following n lines contain table rows. Each row has m column values separated
by commas. Column values consist of ASCII characters from space (ASCII code 32) to tilde (ASCII code 126) with the exception of comma (ASCII code 44). Values are not empty and have no leading and trailing spaces. Each row has at most 80 characters (including
separating commas).
Output
If the table is in PNF write to the output file a single word "YES" (without quotes). If the table is not in PNF, then write three lines. On the first line write a single word "NO" (without quotes). On the second line write two
integer row numbers r1 and r2 (1 <= r1, r2 <= n, r1
r2), on the third line write two integer column numbers c1 and c2 (1
<= c1, c2 <= m, c1
c2), so that values in columns c1 and c2 are the same in rows r1 and r2.
Sample Input
Sample Output
//思路:将输入的n行m列的字符串表映射为整数(即map<string,int>),再从m列选两列(即c1,c2)进行枚举,然后从上到下扫描一遍即可(map<PII,int>,两列看成一个二元组对应一个行)。
AC源码:
#include <iostream>
#include <sstream>
#include <cstdio>
#include <string>
#include <map>
#define LOCAL
using namespace std;
const int MAXN=10000+10;
int db[MAXN][15],cnt;
map<string,int> my_map;
int n,m;
typedef pair<int,int> PII;
int ID(const string& s)
{
if(!my_map.count(s))
my_map[s]=++cnt;
return my_map[s];
}
void solve()
{
map<PII,int> data_set;
for(int c1=0;c1<m;++c1)
{
for(int c2=c1+1;c2<m;++c2)
{
data_set.clear();
for(int r=0;r<n;++r)
{
PII x=make_pair(db[r][c1],db[r][c2]);
if(data_set.count(x))
{
printf("NO\n");
printf("%d %d\n",data_set[x]+1,r+1);
printf("%d %d\n",c1+1,c2+1);
return ;
}
data_set[x]=r;
}
}
}
printf("YES\n");
}
int main()
{
#ifdef LOCA
freopen("data.in","r",stdin);
freopen("data.out","w",stdout);
#endif
string s;
while(getline(cin,s))
{
stringstream ss(s);
if(!(ss>>n>>m))
break;
cnt=0;
my_map.clear();
for(int i=0;i<n;++i)
{
getline(cin,s);
int a=0,b;
for(int j=0;j<m;++j)
{
b=s.find(',',a);
// cout<<"b:"<<b<<endl;
if(b==string::npos)
{
db[i][j]=ID(s.substr(a,b-a));
}
else
{
db[i][j]=ID(s.substr(a,b-a));
a=b+1;
}
}
}
/* for(int i=0;i<n;++i)
{
for(int j=0;j<m;++j)
cout<<db[i][j];
cout<<endl;
}
*/
solve();
}
return 0;
}
There are different normal forms that database may adhere to. Normal forms are designed to minimize the redundancy of data in the database. For example, a database table for a library might have a row for each book and columns for book name, book author, and
author's email.
If the same author wrote several books, then this representation is clearly redundant. To formally define this kind of redundancy Peter has introduced his own normal form. A table is in Peter's Normal Form (PNF) if and only if there is no pair of rows and a
pair of columns such that the values in the corresponding columns are the same for both rows.
How to compete in ACM ICPC | Peter | peter@neerc.ifmo.ru |
How to win ACM ICPC | Michael | michael@neerc.ifmo.ru |
Notes from ACM ICPC champion | Michael | michael@neerc.ifmo.ru |
However, if we introduce unique author identifier and split this table into two tables - one containing book name and author id, and the other containing book id, author name, and author email, then both resulting tables will be in PNF.
How to compete in ACM ICPC | 1 |
How to win ACM ICPC | 2 |
Notes from ACM ICPC champion | 2 |
1 | Peter | peter@neerc.ifmo.ru |
2 | Michael | michael@neerc.ifmo.ru |
Input
The first line of the input file contains two integer numbers n and m (1 <= n <= 10 000, 1 <= m <= 10), the number of rows and columns in the table. The following n lines contain table rows. Each row has m column values separated
by commas. Column values consist of ASCII characters from space (ASCII code 32) to tilde (ASCII code 126) with the exception of comma (ASCII code 44). Values are not empty and have no leading and trailing spaces. Each row has at most 80 characters (including
separating commas).
Output
If the table is in PNF write to the output file a single word "YES" (without quotes). If the table is not in PNF, then write three lines. On the first line write a single word "NO" (without quotes). On the second line write two
integer row numbers r1 and r2 (1 <= r1, r2 <= n, r1
r2), on the third line write two integer column numbers c1 and c2 (1
<= c1, c2 <= m, c1
c2), so that values in columns c1 and c2 are the same in rows r1 and r2.
Sample Input
Sample Input #1: 3 3 How to compete in ACM ICPC,Peter,peter@neerc.ifmo.ru How to win ACM ICPC,Michael,michael@neerc.ifmo.ru Notes from ACM ICPC champion,Michael,michael@neerc.ifmo.ru Sample Input #2: 2 3 1,Peter,peter@neerc.ifmo.ru 2,Michael,michael@neerc.ifmo.ru
Sample Output
Sample Output #1: NO 2 3 2 3 Sample Output #2: YES
//思路:将输入的n行m列的字符串表映射为整数(即map<string,int>),再从m列选两列(即c1,c2)进行枚举,然后从上到下扫描一遍即可(map<PII,int>,两列看成一个二元组对应一个行)。
AC源码:
#include <iostream>
#include <sstream>
#include <cstdio>
#include <string>
#include <map>
#define LOCAL
using namespace std;
const int MAXN=10000+10;
int db[MAXN][15],cnt;
map<string,int> my_map;
int n,m;
typedef pair<int,int> PII;
int ID(const string& s)
{
if(!my_map.count(s))
my_map[s]=++cnt;
return my_map[s];
}
void solve()
{
map<PII,int> data_set;
for(int c1=0;c1<m;++c1)
{
for(int c2=c1+1;c2<m;++c2)
{
data_set.clear();
for(int r=0;r<n;++r)
{
PII x=make_pair(db[r][c1],db[r][c2]);
if(data_set.count(x))
{
printf("NO\n");
printf("%d %d\n",data_set[x]+1,r+1);
printf("%d %d\n",c1+1,c2+1);
return ;
}
data_set[x]=r;
}
}
}
printf("YES\n");
}
int main()
{
#ifdef LOCA
freopen("data.in","r",stdin);
freopen("data.out","w",stdout);
#endif
string s;
while(getline(cin,s))
{
stringstream ss(s);
if(!(ss>>n>>m))
break;
cnt=0;
my_map.clear();
for(int i=0;i<n;++i)
{
getline(cin,s);
int a=0,b;
for(int j=0;j<m;++j)
{
b=s.find(',',a);
// cout<<"b:"<<b<<endl;
if(b==string::npos)
{
db[i][j]=ID(s.substr(a,b-a));
}
else
{
db[i][j]=ID(s.substr(a,b-a));
a=b+1;
}
}
}
/* for(int i=0;i<n;++i)
{
for(int j=0;j<m;++j)
cout<<db[i][j];
cout<<endl;
}
*/
solve();
}
return 0;
}
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