Idea: BledDest
Tutorial
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Solution 1 (awoo)
for _ in range(int(input())):
n, m = map(int, input().split())
for _ in range(m):
input()
print("NO" if n == m else "YES")
Solution 2 (awoo)
#include <bits/stdc++.h>
#define forn(i, n) for (int i = 0; i < int(n); i++)
using namespace std;
int main() {
int t;
scanf("%d", &t);
forn(_, t){
int n, m;
scanf("%d%d", &n, &m);
vector<pair<int, int>> a(m);
forn(i, m){
scanf("%d%d", &a[i].first, &a[i].second);
--a[i].first, --a[i].second;
}
bool ans = false;
forn(i, m) forn(x, n) forn(y, n) if ((x == a[i].first) ^ (y == a[i].second)){
bool ok = true;
forn(j, m) if (i != j){
ok &= x != a[j].first && y != a[j].second;
}
ans |= ok;
}
puts(ans ? "YES" : "NO");
}
}
Idea: BledDest
Tutorial
Tutorial is loading...
Solution (adedalic)
fun main() {
repeat(readLine()!!.toInt()) {
val n = readLine()!!.toInt()
val a = readLine()!!.split(' ').map { it.toLong() }
val b = readLine()!!.split(' ').map { it.toLong() }
println(a.sum() + b.sum() - b.maxOrNull()!!)
}
}
Idea: BledDest
Tutorial
Tutorial is loading...
Solution (Neon)
#include <bits/stdc++.h>
using namespace std;
int main() {
int t;
cin >> t;
while (t--) {
int n;
cin >> n;
vector<int> a(n);
for (int &x : a) cin >> x;
int ans = 0;
for (int k = 1; k <= n; ++k) {
multiset<int> s(a.begin(), a.end());
for (int i = 0; i < k; ++i) {
auto it = s.upper_bound(k - i);
if (it == s.begin()) break;
s.erase(--it);
if (!s.empty()) {
int x = *s.begin();
s.erase(s.begin());
s.insert(x + k - i);
}
}
if (s.size() + k == n) ans = k;
}
cout << ans << '\n';
}
}
Idea: BledDest
Tutorial
Tutorial is loading...
Solution (BledDest)
#include <bits/stdc++.h>
using namespace std;
const int MOD = 998244353;
int add(int x, int y)
{
x += y;
while(x >= MOD) x -= MOD;
while(x < 0) x += MOD;
return x;
}
int sub(int x, int y)
{
return add(x, -y);
}
int mul(int x, int y)
{
return (x * 1ll * y) % MOD;
}
int binpow(int x, int y)
{
int z = 1;
while(y)
{
if(y & 1) z = mul(z, x);
x = mul(x, x);
y >>= 1;
}
return z;
}
bool prime(int x)
{
for(int i = 2; i * 1ll * i <= x; i++)
if(x % i == 0)
return false;
return true;
}
int main()
{
int n;
long long m;
cin >> n >> m;
int ans = 0;
for(int i = 1; i <= n; i++)
ans = add(ans, binpow(m % MOD, i));
long long cur = 1;
int cnt = 1;
for(int i = 1; i <= n; i++)
{
if(cur > m) continue;
if(prime(i)) cur *= i;
cnt = mul(cnt, (m / cur) % MOD);
ans = sub(ans, cnt);
}
cout << ans << endl;
}
Idea: BledDest
Tutorial
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Solution (Neon)
#include <bits/stdc++.h>
using namespace std;
const int INF = 1e9;
int dx[] = {0, 1, 0, -1, 1, 1, -1, -1};
int dy[] = {1, 0, -1, 0, -1, 1, -1, 1};
int main() {
ios::sync_with_stdio(false); cin.tie(0);
int t;
cin >> t;
while (t--) {
int n, m;
cin >> n >> m;
vector<string> s(n);
for (auto &it : s) cin >> it;
auto in = [&](int x, int y) {
return 0 <= x && x < n && 0 <= y && y < m;
};
auto can = [&](int x, int y) {
if (!in(x, y)) return false;
for (int i = 0; i < 4; ++i) {
int nx = x + dx[i], ny = y + dy[i];
if (in(nx, ny) && s[nx][ny] == '#')
return false;
}
return true;
};
vector<vector<int>> d(n, vector<int>(m, INF)), p(n, vector<int>(m));
deque<pair<int, int>> q;
for (int i = 0; i < n; ++i) {
if (s[i][0] == '#') {
d[i][0] = 0;
q.push_front({i, 0});
} else if (can(i, 0)) {
d[i][0] = 1;
q.push_back({i, 0});
}
}
while (!q.empty()) {
auto [x, y] = q.front();
q.pop_front();
for (int i = 4; i < 8; ++i) {
int nx = x + dx[i], ny = y + dy[i];
if (!can(nx, ny)) continue;
int w = (s[nx][ny] != '#');
if (d[nx][ny] > d[x][y] + w) {
d[nx][ny] = d[x][y] + w;
p[nx][ny] = i;
if (w) q.push_back({nx, ny});
else q.push_front({nx, ny});
}
}
}
int x = 0, y = m - 1;
for (int i = 0; i < n; ++i) if (d[x][y] > d[i][y])
x = i;
if (d[x][y] == INF) {
cout << "NO\n";
continue;
}
while (true) {
s[x][y] = '#';
int i = p[x][y];
if (!i) break;
x -= dx[i];
y -= dy[i];
}
cout << "YES\n";
for (auto it : s) cout << it << '\n';
}
}
Tutorial
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Solution (adedalic)
#include<bits/stdc++.h>
using namespace std;
#define fore(i, l, r) for(int i = int(l); i < int(r); i++)
#define sz(a) int((a).size())
typedef long long li;
typedef pair<int, int> pt;
const int INF = int(1e9);
const li INF64 = li(1e18);
const int N = int(2e5) + 55;
const int LOG = 18;
int n;
vector<int> g[N];
inline bool read() {
if(!(cin >> n))
return false;
fore (i, 0, n - 1) {
int u, v;
cin >> u >> v;
u--, v--;
g[u].push_back(v);
g[v].push_back(u);
}
return true;
}
int p[LOG][N];
int tin[N], tout[N], T = 0;
void build(int v, int pr) {
tin[v] = T++;
p[0][v] = pr;
fore (pw, 1, LOG)
p[pw][v] = p[pw - 1][p[pw - 1][v]];
for (int to : g[v]) {
if (to == pr)
continue;
build(to, v);
}
tout[v] = T;
}
bool inside(int l, int v) {
return tin[l] <= tin[v] && tout[v] <= tout[l];
}
int lca(int u, int v) {
if (inside(u, v))
return u;
if (inside(v, u))
return v;
for (int pw = LOG - 1; pw >= 0; pw--) {
if (!inside(p[pw][u], v))
u = p[pw][u];
}
return p[0][u];
}
const int D = 21;
struct Fenwick {
int n;
vector<int> F;
void init(int nn) {
n = nn;
F.assign(n, 0);
}
void add(int pos, int val) {
for (; pos < n; pos |= pos + 1)
F[pos] += val;
}
int sum(int pos) {
int ans = 0;
for (; pos >= 0; pos = (pos & (pos + 1)) - 1)
ans += F[pos];
return ans;
}
int getSum(int l, int r) {
return sum(r - 1) - sum(l - 1);
}
};
struct DS {
Fenwick f;
void init(int n) {
f.init(n);
}
void addPath(int v, int l, int k) {
f.add(tin[v], +k);
f.add(tin[l], -k);
}
int getVertex(int v) {
return f.getSum(tin[v], tout[v]);
}
void addVertex(int v, int k) {
f.add(tin[v], +k);
if (p[0][v] != v)
f.add(tin[p[0][v]], -k);
}
};
DS t[D];
inline void solve() {
fore (i, 0, D) {
g[n - 1 + i].push_back(n + i);
g[n + i].push_back(n - 1 + i);
}
int root = n + D - 1;
build(root, root);
fore (i, 0, D)
t[i].init(root + 1);
int m; cin >> m;
fore(_, 0, m) {
int tp; cin >> tp;
if (tp == 1) {
int v; cin >> v;
v--;
int ans = 0;
for (int i = 0, cur = v; i < D; i++, cur = p[0][cur])
ans += t[i].getVertex(cur);
cout << ans << endl;
}
else {
assert(tp == 2);
int u, v, k, d;
cin >> u >> v >> k >> d;
u--, v--;
int l = lca(u, v);
if (u != l)
t[d].addPath(u, l, k);
if (v != l)
t[d].addPath(v, l, k);
for (int i = 0; i <= d; i++, l = p[0][l]) {
t[d - i].addVertex(l, k);
if (d - i > 0)
t[d - i - 1].addVertex(l, k);
}
}
}
}
int main() {
#ifdef _DEBUG
freopen("input.txt", "r", stdin);
int tt = clock();
#endif
ios_base::sync_with_stdio(false);
cin.tie(0), cout.tie(0);
cout << fixed << setprecision(15);
if(read()) {
solve();
#ifdef _DEBUG
cerr << "TIME = " << clock() - tt << endl;
tt = clock();
#endif
}
return 0;
}
Thank you!
Top 3 reason for depression
1)breakup
2)Substance Abuse
2)WA in div2 C
Can you somehow solve F using centroid decomposition?
My Solution for the problem 1749D — Counting Arrays. (Python)
Simple
Commented One
I was trying to solve problem E using BFS + backpointer table for tracing steps. I have been debugging for an hour, but can't figure out why my solution is not optimal — is there a bug somewhere? Can someone pls help?
https://mirror.codeforces.com/contest/1749/submission/177375163
Great problems !
In D, I understand that if the i-th element is not "bad"(it can be removed only if it is at position 1), it's factors must contain all primes from 1 to i.
My question is: Why the number of good(not bad) elements is $$$\dfrac{m}{p_1p_2...p_k}$$$, where $$$p_k$$$ is mentioned in the editorial. Could somebody enlighten me why it is obvious :(
For position i if you call an element not bad if it can only be removed at the first position, then the element must be divisible by all the prime numbers present in [1,i]. Let's say there are k prime numbers in [1,i] : p1, p2, p3...pk.
Now, what is the smallest valid not bad element for the position i could be?
It would be: L.C.M(p1,p2,...pk) = p1.p2.p3....pk
What are the other valid not bad elements possible for the position i?
It would the Multiples of L.C.M(p1,p2,...pk) = p1.p2.p3....pk
How many valid not bad elements possible for the position i in [1,m]
m/L.C.M(p1,p2...pk)
You mentioned multiples, now I can see why. Thanks very much!
Can someone tell me why this code for problem E is always wrong?
I have debuged it for 3 hours TAT
Take a look at Ticket 16349 from CF Stress for a counter example.
OH!THANKS!
Can anyone explain why the problem 1749E — Cactus Wall the path carved out by 0-1 DFS would always satisfy cacti cannot grow on cells adjacent to each other by side as we are not storing the cacti in the current path(only checking the initial cacti)?
Note that we do BFS traversal in an order that satisfy the initial constraints as well as we maintain the constraints by traversing diagonally. It suffices to check this, since only one of the path will be our answer (which will obviously satisfy the constraints as it has been constructed that way).
TLDR : Since we only traverse diagonally to construct the path, the constraint is maintained for all paths (individually). This is necessary and sufficient.
The key observation of problem E is very interesting. I'm wondering if we can generalize this problem.
Say you're given a map consisting of '.', '#', 'A' and 'B'. You need to grow cactus so that one cannot go from an 'A' cell to a 'B' cell. In this case how can we find the starting and the ending point of the shortest path?
For example for the following map:
one must grow cactus like this:
We can't just start from an arbitrary cell in the first column and ends at another arbitrary cell in the last column. There seems to be more restrictions.
In C, Obviously, it is more profitable for Bob to "prohibit" the smallest element of the array
Not to me. What about the case when Bob, using this tactics, takes the same integer multiple times? What if during her turn, Alice couldn't have taken all of them anyways? So that Bob wasted some moves and could rather take some other elements that Alice already took?
Could you show the proof that such situation never happens? It really puzzled me during the contest and still does. Any help is appreciated.
Not sure of your example. But i can try to explain the first line.
Let's suppose there are some elements and each time Alice can remove element <= k-i+1 and bob can add the same amount to any element after Alice's turn. So if you see k-i+1 is decreasing and after Alice chance, if bob is going to add any k-i+1 to any element it will surely go beyond the scope of Alice next chance no matter how small or big number bob added it on(take any example and verify it). So bob will always try to take the smallest number as it will decrease Alice's chance to select element with k-i+1 condition in next turn. whereas if bob had selected any other number there is possibility Alice might use smallest in next turn.
You can think of this problem as Alice remove one element and then Bob is also removing one element by increasing it byeond the Alice's scope.
whereas if bob had selected any other number there is possibility Alice might use smallest in next turn.
This is what I was looking for! Mystery solved, thanks!
I can't prove the following lemma used in Problem E
It is very intuitive to see it by drawing some pictures, but I just can't get around proving it formally. I tried induction on $$$n•m$$$, greedy proof strategies etc. But nothing seems to work. Any help? BledDest
For C: Number game, I had a solution that is
O(nlogn)
, although I understand the constraints didn't require it. the idea was binary search for k.I devised a function "doesKWork" that takes inputs as the k to check and also an array where a[i] stores the number of elements lesser than or equal to i present in the original array.
for k to be a valid number such that Alice wins in optimal play by bob, this must be the condition satisfied. each lEq[i] >= k+i-1. then its just simple binary search for k.
You can check my submission for reference 177187641
Can you explain the k + i — 1 condition
In problem D, why isn't the total number of arrays just $$$m^n$$$ ? Why should we take $$$m^1 + m^2 + ...+m^n$$$ ?
"You have to calculate the number of ambiguous arrays $$$a$$$ such that the length of $$$a$$$ is from $$$1$$$ to $$$n$$$"
in problem C, what i am thinking is that we will first vector in which values are stored then take values one by one from left but i dont understand what does stages mean here
Really sorry for necroposting. Can anyone please help me why my code is giving WA in D.
269406458
My solution is exactly like Author's solution. But I can't figure out what is wrong with my code. I have thought it for hours and still can't figure out the problem with my code.
Sieve is for calculating prime numbers(though it is unnecessary). dq stores prime numbers upto 100. total = m^1+m^2+⋯+m^n. res stores the number of unambiguous arrays.
Sorry for my bad English.