第一次点进去,结果忘记参赛了。。。但还是做了2个题(水平低到没底。。请轻虐。。)下面是题和我做的不确定是否正确的解决方案。
原题链接:http://codeforces.com/contest/1025
Panic is rising in the committee for doggo standardization — the puppies of the new brood have been born multi-colored! In total there are 26 possible colors of puppies in the nature and they are denoted by letters from 'a' to 'z' inclusive.
The committee rules strictly prohibit even the smallest diversity between doggos and hence all the puppies should be of the same color. Thus Slava, the committee employee, has been assigned the task to recolor some puppies into other colors in order to eliminate the difference and make all the puppies have one common color.
Unfortunately, due to bureaucratic reasons and restricted budget, there's only one operation Slava can perform: he can choose a color xxsuch that there are currently at least two puppies of color xx and recolor all puppies of the color xx into some arbitrary color yy. Luckily, this operation can be applied multiple times (including zero).
For example, if the number of puppies is 77 and their colors are represented as the string "abababc", then in one operation Slava can get the results "zbzbzbc", "bbbbbbc", "aaaaaac", "acacacc" and others. However, if the current color sequence is "abababc", then he can't choose xx='c' right now, because currently only one puppy has the color 'c'.
Help Slava and the committee determine whether it is possible to standardize all the puppies, i.e. after Slava's operations all the puppies should have the same color.
The first line contains a single integer nn (1≤n≤1051≤n≤105) — the number of puppies.
The second line contains a string ss of length nn consisting of lowercase Latin letters, where the ii-th symbol denotes the ii-th puppy's color.
If it's possible to recolor all puppies into one color, print "Yes".
Otherwise print "No".
Output the answer without quotation signs.
6
aabddc
Yes
3
abc
No
3
jjj
Yes
In the first example Slava can perform the following steps:
- take all puppies of color 'a' (a total of two) and recolor them into 'b';
- take all puppies of color 'd' (a total of two) and recolor them into 'c';
- take all puppies of color 'b' (three puppies for now) and recolor them into 'c'.
In the second example it's impossible to recolor any of the puppies.
In the third example all the puppies' colors are the same; thus there's no need to recolor anything.
#include <bits/stdc++.h>
#define Index(ch) (ch - 'a')
const int N = 100000;
int has[26];
void init(char*c, int s)
{
memset(has, 0, 26);
for (int i = 0; i < s; i++)
has[Index(c[i])]++;
}
int main()
{
char cors[N];int dogs;
while (~scanf("%d", &dogs))
{
if (dogs > 1 && dogs < N)
{
scanf("%s", cors);
init(cors, dogs);
for (int i = 0; i < 26; i++)
if (has[i] >= 2)
{
dogs = 0;
break;
}
if (!dogs)
puts("Yes");
else
puts("No");
}
else
puts("No");
}
return 0;
}
During the research on properties of the greatest common divisor (GCD) of a set of numbers, Ildar, a famous mathematician, introduced a brand new concept of the weakened common divisor (WCD) of a list of pairs of integers.
For a given list of pairs of integers (a1,b1)(a1,b1), (a2,b2)(a2,b2), ..., (an,bn)(an,bn) their WCD is arbitrary integer greater than 11, such that it divides at least one element in each pair. WCD may not exist for some lists.
For example, if the list looks like [(12,15),(25,18),(10,24)][(12,15),(25,18),(10,24)], then their WCD can be equal to 22, 33, 55 or 66 (each of these numbers is strictly greater than 11 and divides at least one number in each pair).
You're currently pursuing your PhD degree under Ildar's mentorship, and that's why this problem was delegated to you. Your task is to calculate WCD efficiently.
The first line contains a single integer nn (1≤n≤1500001≤n≤150000) — the number of pairs.
Each of the next nn lines contains two integer values aiai, bibi (2≤ai,bi≤2⋅1092≤ai,bi≤2⋅109).
Print a single integer — the WCD of the set of pairs.
If there are multiple possible answers, output any; if there is no answer, print −1−1.
3
17 18
15 24
12 15
6
2
10 16
7 17
-1
5
90 108
45 105
75 40
165 175
33 30
5
In the first example the answer is 66 since it divides 1818 from the first pair, 2424 from the second and 1212 from the third ones. Note that other valid answers will also be accepted.
In the second example there are no integers greater than 11 satisfying the conditions.
In the third example one of the possible answers is 55. Note that, for example, 1515 is also allowed, but it's not necessary to maximize the output.
#include <bits/stdc++.h>
const int N = 150000;
int a[N], b[N];
int gcd(int a, int b)
{
if (b == 0) return a;
return gcd(b, a%b);
}
int main()
{
int s;
while (~scanf("%d", &s))
{
int p1, p2, p3, p4, f1 = 0, f2 = 0, f3 = 0, f4 = 0;
for (int i = 0; i < s; i++)
scanf("%d %d", &a[i], &b[i]);
p1 = gcd(a[0], a[1]);
p2 = gcd(a[0], b[1]);
p3 = gcd(b[0], a[1]);
p4 = gcd(b[0], b[1]);
if (p1 > 1)
{
f1 = p1;
for (int i = 2; i < s; i++)
p1 = gcd(p1, a[i]);
for (int i = 2; i < s; i++)
f1 = gcd(f1, b[i]);
}
if (p2 > 1)
{
f2 = p2;
for (int i = 2; i < s; i++)
p2 = gcd(p2, a[i]);
for (int i = 2; i < s; i++)
f2 = gcd(f2, b[i]);
}
if (p3 > 1)
{
f3 = p3;
for (int i = 2; i < s; i++)
p3 = gcd(p3, a[i]);
for (int i = 2; i < s; i++)
f3 = gcd(f3, b[i]);
}
if (p4 > 1)
{
f4 = p4;
for (int i = 2; i < s; i++)
p4 = gcd(p4, a[i]);
for (int i = 2; i < s; i++)
f4 = gcd(f4, b[i]);
}
if (p1 > 1) printf("%d
", p1);
else if (f1 > 1) printf("%d
", f1);
else if (p2 > 1) printf("%d
", p2);
else if (f2 > 1) printf("%d
", f2);
else if (p3 > 1) printf("%d
", p3);
else if (f3 > 1) printf("%d
", f3);
else if (p4 > 1) printf("%d
", p4);
else if (f4 > 1) printf("%d
", f4);
else
puts("-1");
}
return 0;
}
Dima the hamster enjoys nibbling different things: cages, sticks, bad problemsetters and even trees!
Recently he found a binary search tree and instinctively nibbled all of its edges, hence messing up the vertices. Dima knows that if Andrew, who has been thoroughly assembling the tree for a long time, comes home and sees his creation demolished, he'll get extremely upset.
To not let that happen, Dima has to recover the binary search tree. Luckily, he noticed that any two vertices connected by a direct edge had their greatest common divisor value exceed 11.
Help Dima construct such a binary search tree or determine that it's impossible. The definition and properties of a binary search tree can be found here.
The first line contains the number of vertices nn (2≤n≤7002≤n≤700).
The second line features nn distinct integers aiai (2≤ai≤1092≤ai≤109) — the values of vertices in ascending order.
If it is possible to reassemble the binary search tree, such that the greatest common divisor of any two vertices connected by the edge is greater than 11, print "Yes" (quotes for clarity).
Otherwise, print "No" (quotes for clarity).
6
3 6 9 18 36 108
Yes
2
7 17
No
9
4 8 10 12 15 18 33 44 81
Yes
The picture below illustrates one of the possible trees for the first example.
The picture below illustrates one of the possible trees for the third example.
(还在推dp方程中。。。)方程是推不出来了(> <),直接看别人的题解吧:
http://codeforces.com/contest/1025/submission/41898155 Orz...
这里还有一份是循环的区间dp的解法 Orz....:
#include<bits/stdc++.h>
int n,s[704],g[705][705],L[705][705],R[705][705],f[705][705];
int main()
{
for(int i = 0;i <= (n=s[0]); i++)
scanf("%d",&s[i]);
for(int i=1;i<=n;i++)
for(int j=1;j<=n;j++)
g[i][j]=std::__gcd(s[i],s[j])>1;
for(int i=1;i<=n;i++)
L[i][i]=R[i][i]=1;
for(int i=n;i>=1;i--)
for(int j=i;j<=n;j++)
for(int k=i;k<=j;k++)
if(L[i][k] && R[k][j])
f[i][j] |= 1,
R[i-1][j] |= g[k][i-1],
L[i][j+1] |= g[k][j+1];
return puts(f[1][n]?"Yes":"No"),0;
}