$(709/3775)$
将字符串$S=S_0+S_1+S_2+…+S_{n-1}$循环位移$k$次后得到$S(k)=S_{k\bmod n }+…+S_{n-1}+S+0+…+S_{(k-1)\bmod n}$。
定义$[A]={A(k),k\in N}$。给出$T$组串$A,B$,询问$B$有多少个子串在$[A]$中。
- $|A|\leq |B|$
- $\sum|B|\leq 1048576$
记字符串$A$的长度是$n$,将字符串$A$转变为首尾相连的样子($A=A+A.substr(1,n-1)$),并计算其中每个长度为$n$的哈希值,用map存值,再对字符串$B$进行哈希,同样也对长度为$n$的子串计算哈希值,若有符合的则计数。
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| ll ha[maxn], hb[maxn];
ll pwr[maxn];
void solve() {
string a, b;cin >> a >> b;
ll n = a.size();
a = a.substr(1, n - 1) + a;
ll la = a.size(), lb = b.size();
a = " " + a, b = " " + b;
pwr[0] = 1;
map<ll, bool>mp;
for (ll i = 1;i <= la;i++) {
ha[i] = ha[i - 1] * bas1 + a[i];
pwr[i] = pwr[i - 1] * bas1;
if (i - n >= 0) {
ll x = ha[i] - ha[i - n] * pwr[n];
mp[x] = true;
}
}
ll ans = 0;
for (ll i = 1;i <= lb;i++) {
hb[i] = hb[i - 1] * bas1 + b[i];
if (i - n >= 0) {
ll x = hb[i] - hb[i - n] * pwr[n];
if (mp.count(x)) {
ans++;
}
}
}
cout << ans << endl;
}
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$(991/1659)$
小$A$有$n$次获得星星的机会,第$i$次有如下5种选择:
- 跳过
- $a_i$的代价获得$1$颗星星
- $b_i$的代价获得$2$颗星星
- $c_i$的代价获得$3$颗星星
- $d_i$的代价获得$4$颗星星
请问若想恰好获得$k$颗星星,所需要的最小代价是多少。
- $1\leq n\leq 1000$
- $0\leq k\leq n\times 4$
- $0\lt a_i\leq b_i\leq c_i\leq d_i\leq 10^9$
基础的动态规划。记$dp[i]$表示获得$i$颗星星的最小代价。
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| ll a[maxn], b[maxn], c[maxn], d[maxn];
ll dp[4 * maxn];
void solve() {
ll n, k;cin >> n >> k;
for (ll i = 1;i <= n;i++) {
cin >> a[i] >> b[i] >> c[i] >> d[i];
}
fill(dp, dp + 4 * maxn, inf);
dp[0] = 0;
for (ll i = 1;i <= n;i++) {
ll m = min(k, 4 * i);
for (ll j = m;j >= 0;j--) {
if (j + 1 <= m)
dp[j + 1] = min(dp[j] + a[i], dp[j + 1]);
if (j + 2 <= m)
dp[j + 2] = min(dp[j] + b[i], dp[j + 2]);
if (j + 3 <= m)
dp[j + 3] = min(dp[j] + c[i], dp[j + 3]);
if (j + 4 <= m)
dp[j + 4] = min(dp[j] + d[i], dp[j + 4]);
}
}
cout << dp[k] << "\n";
}
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$(918/1427)$
有多少在范围$[0,2^k)$中的$a,b,c,d$构成的四元组$(a,b,c,d)$满足$a \& b\oplus c | d=n$。
- $1\leq T\leq 10$
- $1\leq k\leq 15,0\leq n\lt 2^k$
记$x=a \& b\oplus c | d$,$x$的每一位只有1和0的可能,而每位上的数字只和$a,b,c,d$对应位是$1$或$0$有关,枚举四个数的$1/0$,统计$x$是$0$的组合和是$1$的组合的数量。再根据$n$的$k$位进行统计即可。
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| void solve() {
ll n, k;cin >> n >> k;
ll cnt[2];cnt[0] = cnt[1] = 0;
for (int i = 0;i <= 1;i++) {
for (int j = 0;j <= 1;j++) {
for (int k = 0;k <= 1;k++) {
for (ll l = 0;l <= 1;l++) {
ll x = i & j ^ k | l;
cnt[x]++;
}
}
}
}
vector<int>v;
ll ans = 1;
for (ll i = 0;i < k;i++) {
v.push_back(n & 1);
ans *= cnt[n & 1];
n >>= 1;
}
cout << ans << "\n";
}
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$(241/1229)$
给出在二维平面上的$n$个矩形,随机选择$k$个不同的矩形$(k\in [1,n])$,求这$k$个矩形所有覆盖部分的并集的面积的期望。
- $1\leq n\leq 2\times 10^3$
- $1\leq x_{i,1}\lt x_{i,2} \leq 10^9$
- $1\leq y_{i,1}\lt y_{i,2} \leq 10^9$
将横纵坐标离散化之后可以将这$n$个矩形覆盖的部分分割成不重叠的若干个小矩形,每个小矩形设置权值,代表被原来的$n$个矩形覆盖的次数。设某个小矩形的覆盖次数是$m$,则在选择$k$个矩形时,这个小矩形的贡献是:$\frac{\binom{k}{n}-\binom{k}{n-m}}{\binom{k}{n}}$(全集-选除该矩形以外的部分),预处理离散后的矩形以及被覆盖$m$次的所有矩形的总面积,枚举计数即可。
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| #include<bits/stdc++.h>
using namespace std;
typedef long long ll;
typedef double ld;
const int maxn = 2050;
const int mo998 = 998244353;
struct Rec {
ll x1, y1, x2, y2;
}a[maxn];
ll X[maxn * 2], Y[maxn * 2];
ll fact[maxn], invfact[maxn]; // 阶乘,阶乘逆元
ll qpow(ll a, ll b) {
ll res = 1;
while (b) {
if (b & 1)res = res * a % mo998;
b >>= 1;
a = a * a % mo998;
}
return res;
}
ll inv(ll x) {
return qpow(x, mo998 - 2);
}
void init() {
// 预处理阶乘,阶乘逆元
fact[0] = invfact[0] = 1ll;
for (int i = 1;i < maxn;i++) {
fact[i] = fact[i - 1] * i % mo998;
invfact[i] = invfact[i - 1] * inv(i) % mo998;
}
}
ll C(int n, int k) {
// n选k的方案数
if (k > n)return 0ll;
ll res = fact[n] * invfact[k] % mo998 * invfact[n - k] % mo998;
return res;
}
ll Stot[maxn], rec[2 * maxn][2 * maxn];
void solve() {
int n;cin >> n;
for (int i = 1;i <= n;i++) {
ll x1, y1, x2, y2;
cin >> x1 >> y1 >> x2 >> y2;
a[i] = { x1,y1,x2,y2 };
X[i] = x1, X[i + n] = x2;
Y[i] = y1, Y[i + n] = y2;
}
sort(X + 1, X + 1 + 2 * n);
sort(Y + 1, Y + 1 + 2 * n);
int t1 = unique(X + 1, X + 1 + 2 * n) - X - 1;
int t2 = unique(Y + 1, Y + 1 + 2 * n) - Y - 1;
for (int i = 1;i <= n;i++) {
auto [x1, y1, x2, y2] = a[i];
x1 = lower_bound(X + 1, X + 1 + t1, x1) - X; // 值x1在X[]中的位置
x2 = lower_bound(X + 1, X + 1 + t1, x2) - X;
y1 = lower_bound(Y + 1, Y + 1 + t2, y1) - Y;
y2 = lower_bound(Y + 1, Y + 1 + t2, y2) - Y;
// 差分计数
rec[x1][y1]++, rec[x2][y1]--;
rec[x1][y2]--, rec[x2][y2]++;
}
for (int i = 1;i <= t1;i++) {
for (int j = 1;j <= t2;j++) {
rec[i][j] += rec[i - 1][j] + rec[i][j - 1] - rec[i - 1][j - 1];
}
}
for (int i = 1;i < t1;i++) {
for (int j = 1;j < t2;j++) {
// 覆盖rec[i][j]次的矩形的面积
Stot[rec[i][j]] += (X[i + 1] - X[i]) * (Y[j + 1] - Y[j]) % mo998;
Stot[rec[i][j]] %= mo998;
}
}
for (int k = 1;k <= n;k++) {
ll ans = 0, Cnk = C(n, k);
ll iCnk = inv(Cnk);
for (int i = 1;i <= n;i++) {
ll Si = Stot[i];
ans += (Cnk - C(n - i, k) + mo998) % mo998 * iCnk % mo998 * Si % mo998;
ans %= mo998;
}
cout << ans << "\n";
}
}
int main() {
ios::sync_with_stdio(false);
cin.tie(0);
init();
int t = 1;
// cin >> t;cin.tie(0);
while (t--)
solve();
return 0;
}
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