Блог пользователя n0sk1ll

Автор n0sk1ll, история, 2 года назад, По-английски

1689A - Lex String

Author: wxhtzdy

Hint
Solution
C++ Code

1689B - Mystic Permutation

Author: n0sk1ll

Hint 1
Hint 2
Solution
C++ Code (Main solution)
C++ Code (O(n) solution)

Riblji_Keksic found the O(n) solution.

1689C - Infected Tree

Author: n0sk1ll

Hint 1
Hint 2
Solution
C++ Code

1689D - Lena and Matrix

Author: n0sk1ll

Hint
Solution
C++ Code

1689E - ANDfinity

Author: wxhtzdy

Stupid Hint
Hint 1
Hint 2
Hint 3
Solution
C++ Code
Разбор задач Codeforces Round 798 (Div. 2)
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2 года назад, # |
Rev. 2   Проголосовать: нравится +45 Проголосовать: не нравится

Very fast editorial. Problems were good also.

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    2 года назад, # ^ |
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    Problem were really good, thanks [user:n0sk1||] and wxhtzdy and all the contributors of the contest. I was really a good contest for me.

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2 года назад, # |
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I was not even able to solve A :(

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2 года назад, # |
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Why DP in C? It's just overcomplication, isnt it?

UPD: Idk, i just... Bruh

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    2 года назад, # ^ |
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    what's your approach?

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      2 года назад, # ^ |
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      You can check out my solution https://codeforces.me/contest/1689/submission/160137279 . The idea is that we can make the infection infect only one vertex at a time, or non at all, If the vertex has two children, we delete one of them and make the infection spread to the other child, so both children die, and this process continues unless one of their children has only one child so infection can not spread anymore, then you just cut one source and infection can not spread at all.

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        2 года назад, # ^ |
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        What is the use of variable 'dis' in your code and why are you returning (dis+1) at some places, (dis+2) at other places, and just (dis) at some other places?
        Can you please explain a bit?

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          2 года назад, # ^ |
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          It denotes the amount of vertex that dies, so if the vertex has two children, both of them die, so I do dis+2, if it only has one, only one dies, if it has none, then none dies and I just return dis.

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      2 года назад, # ^ |
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      You can just simply use recursion. My solution: https://codeforces.me/contest/1689/submission/160139911

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    2 года назад, # ^ |
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    ig we can just store subtree count of every node & later add by processing in valid manner

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    2 года назад, # ^ |
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    we can solve c without dp.the approch is simply follow along the infected path along the binary tree using dfs/bfs,take minimum of the available infected paths and saved =(n-(infected)) my solution approch

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    2 года назад, # ^ |
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    Agreed. For anyone who isn't aware, the non-DP approach is to let $$$v$$$ be the least deep vertex with at most one child. Then, the number of vertices that must be lost is $$$d(v) + c(v) + 1$$$, where $$$d(v)$$$ is the depth of $$$v$$$ (where the root has depth $$$1$$$) and $$$c(v)$$$ is the number of children of $$$v$$$.

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      2 года назад, # ^ |
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      I am probably being stupid, but why is d(v) being multiplied by 2?

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        2 года назад, # ^ |
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        For each two-child vertex down which the virus spreads, you lose both the child onto which the virus spreads and the other child, which you must shut down to keep the virus from spreading onto the other branch.

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      2 года назад, # ^ |
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      whats the proof for this?

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        2 года назад, # ^ |
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        After reading Geothermal's second comment, I had to think carefully and visualize a tree that had layers of two-child vertices followed by a single- or no-child vertex. Then it became clear.

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    2 года назад, # ^ |
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    I hate you, i really hate you people

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2 года назад, # |
  Проголосовать: нравится +4 Проголосовать: не нравится

fastest editorial ever? nice

very fun, wish I could do more than 3

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    2 года назад, # ^ |
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    I don't think so there was recently a contest in which they update the rating and the editorial was out the minute contest and system testing ended. It was Instant no delay.

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2 года назад, # |
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In problem C, wish there was a test case in the sample, where the input had an edge connecting from child node to parent node.

Initially I assumed that, the edges were always from parent to child, and wasted time.

I know it is my fault for making wrong assumption. But still :(.

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    2 года назад, # ^ |
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    I wasted half of my time trying to code a greedy algorithm, and only realized halfway through that it was supposed to be dp, so that was kinda sad lol.

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2 года назад, # |
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Cool

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2 года назад, # |
Rev. 2   Проголосовать: нравится +4 Проголосовать: не нравится

O(n) solution for B.

The smallest possible lexicographic permutation is 1,2,3,4... Assume that this is the answer. Now just check if any element of the answer array matches with input permutation. if yes, swap it with next element. It's easy to see that no conflict would arise in this manner. There's edge case for last index, we have to swap it with previous element.

My submission- https://codeforces.me/contest/1689/submission/160104354

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2 года назад, # |
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The problem IDs in the editorial are shown as the gym IDs (probably, some testing mashup). Please fix it.

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2 года назад, # |
Rev. 2   Проголосовать: нравится -64 Проголосовать: не нравится
// My solution for A:

#include "bits/stdc++.h"
using namespace std;


void solve();
int main()
{
    ios_base::sync_with_stdio(false);
    cin.tie(NULL); 

    int tc;
    cin >> tc; 

    while(tc--)  
    {
        solve(); 
    }
    return 0;
}
void solve(){
    int n, m, k; cin >> n >> m >> k;
    string a, b, c = ""; cin >> a >> b; 
    sort(a.begin(), a.end());
    sort(b.begin(), b.end());
    int i = 0, j = 0, turn = 0;
    if(a[i] > b[j])
    turn = 1;
    if(a[i] == b[j] && n > m)
    turn = 1;
    while(i < n && j < m)
    {
        if(turn == 0)
        {
            c += a[i]; i++;
            for(int t = 1; i<n && a[i]<=b[j] && t < k; i++, t++)
            c += a[i];
            turn = 1;
        }
        else
        {
            c += b[j]; j++;
            for(int t = 1; j<m && b[j]<=a[i] && t < k; j++, t++)
            c += b[j];
            turn = 0;
        }
    }
    cout << c << endl;
}
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2 года назад, # |
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balanced round with good problems keep it up

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2 года назад, # |
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cool problems and well organized overall a very good contest.thanks:)

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2 года назад, # |
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Problem C can be solved greedily. I just find the shortest path from root to the node which have less than 2 children and infected those node and saved all other nodes by deleting the first node of every subtree connected to these infected nodes.

Code
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    2 года назад, # ^ |
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    Nice Observation! What is cnt in your code?

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      2 года назад, # ^ |
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      cnt represent that the last node has any child or not . If the last node has no child then there is no subtree connected to that node and in that case there is one less node to delete. That's why when cnt is 1(no child) the output is n-2*(ans+1)+1 which is equal to n-(ans+1)-ans and in the case where cnt is 2(has one child) the output is n-2*(ans+1)

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    2 года назад, # ^ |
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    I solved C absolutely the same way as you

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    2 года назад, # ^ |
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    what does this part of the code do?


    if(sz<3){
            if(dis<ans){
                ans=min(ans,dis);
                cnt=sz;
            }else if(dis==ans){
                cnt=min(cnt,sz);
            }
            return;
        }
    
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      2 года назад, # ^ |
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      If sz is less than 3 this means that the node has only one child or no child so the path ends here and I am just taking the minimum of all the path from root to the node having no or one child and cnt just stores that the last node has a child or not

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2 года назад, # |
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Why is this getting MLE ?

My code for C : 160135752

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    2 года назад, # ^ |
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    Your solve function is called recursively infinite times as it is calling its parent node in some test cases like the below one.

    Test Case:
    5
    2 3
    5 1
    4 2
    1 2
    
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2 года назад, # |
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The hint 3 in problem E tells that answer is 0, 1 or 2. But we have an answer 3 in the example.

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2 года назад, # |
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Can someone please explain problem C? Since it is a binary tree there will always be at max two edges from the root node. I calculated the indegree of both and subtracted the minimum to find the max nodes which can be saved but this approach is giving wrong answer on test 3. Pls Help

https://p.ip.fi/4svQ

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2 года назад, # |
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they didn't thought that C can be solved using DFS?

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2 года назад, # |
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For D, another approach is to use the fact that $$$abs(x) = max(x, -x)$$$.

Let $$$S$$$ be the set of black cell, then we need to minimize: $$$max(abs(i - x) + abs(j - y))$$$ for every combination of $$$1\leq i \leq n, 1\leq j \leq m, (x, y) \in S$$$.

This is just $$$max(max(i - x, x - i) + max(j - y, y - j))$$$.

Just expand the inner $$$max$$$ and we will have 4 cases to check, similar to the official tutorial.

160104327

I think this idea ($$$abs(x) = max(x, -x)$$$) is pretty common but still very powerful, probably would have taken much more time to solve D if I didn't know it.

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    2 года назад, # ^ |
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    When I tested the round, I immediately recognized the problem as one where you need to transform the coordinates in such a way that the Manhattan metric becomes the Chebyshev metric (which corresponds to rotation by 45 degrees and appropriate scaling). $$$|x| = \max \{x, -x\}$$$ is basically why that transformation works. I was also opposed to adding this problem in the contest because 1658E - Gojou and Matrix Game is a strictly harder version of the problem.

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    2 года назад, # ^ |
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    In the 4 cases that we make on expanding the max, there is an underlying condition for every case right, for example, only when $$$i \leq x$$$ and $$$j \leq y$$$, we get the Manhattan distance as $$$x + y - (i + j)$$$, but in your implementation, you have directly chosen the maximum value of $$$x + y$$$, (say it is $$${(x+y)}_{max}$$$) and you've taken the maximum of $$$cost$$$ and $$$(x+y)_{max} - (i+j)$$$ without checking if $$$i\leq x$$$ and $$$j\leq y$$$. Can you please explain the thought process behind this and why this works?

    Edit: I misunderstood what you meant by "expanding the inner max", I got it now, thanks.

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      2 года назад, # ^ |
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      Yes, writing out the expansion more explicitly for anyone who doesn't see it, it is equal to $$$\max_{(x,y) \in S} \max(i-x+j-y,i-x+y-j,x-i+j-y,x-i+y-j)$$$ $$$= \max( \max_{(x,y) \in S} (i-x+j-y), \max_{(x,y) \in S} (i-x+y-j), \max_{(x,y) \in S} (x-i+j-y), \max_{(x,y) \in S} (x-i+y-j))$$$ $$$= \max(i+j + \max_{(x,y) \in S} (-x-y), i-j + \max_{(x,y) \in S} (-x+y), j-i + \max_{(x,y) \in S} (x-y), -i-j + \max_{(x,y) \in S} (x+y) ),$$$ and you can precompute each of the four terms $$$\max_{(x,y) \in S} (ax + by)$$$ for $$$a,b \in {-1,1}.$$$

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        2 года назад, # ^ |
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        Can we use a similar method when we need to find the minimum Manhattan distance among all pair of points? Just replacing the outer MAX by MIN, whereas inner MAX remains same, as it corresponds to the 'abs' thing.

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    2 года назад, # ^ |
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    I think a simpler solution is to transform the Manhattan distance to Chebyshev distance, and we only need to minimize $$$\max_{1\le i\le k} {\max(|a'-x_i'|,|b'-y_i'|)}=max(\max_{1\le i\le k}|a'-x_i'|,\max_{1\le i\le k}|b'-y_i'|)$$$, which is optimal when choosing the median among the $$$x$$$ and $$$y$$$ coordinates of given points.

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      2 года назад, # ^ |
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      Sorry, I didn't see that the tester above had already shared this solution.

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2 года назад, # |
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Problem D can also be solved by dp.
But we have to maintain 4 dp tables. One table dp[i][j] stores max distance of a black point from i,j in top left of the matrix and other tables will store for other three part of matrix which is top-right, bottom-left and bottom-right . Max distance of a point from black point will be max of the value from all four table and then we can take minimum of all these and that will be our answer .

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    2 года назад, # ^ |
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    Even just 2 dp tables are sufficient... One storing max distance of a black cell with x coordinate < i & other with x coordinate >= i for a given (i,j)

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      2 года назад, # ^ |
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      nice solution. I missed the idea of using first and last rows per column

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      2 года назад, # ^ |
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      can you explain more ? i didn't get what you mean by max dist. < i . Like what does this signify?

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        2 года назад, # ^ |
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        For each point (i,j), we want to know the max distance of a black cell from it. Once we know this, we can simply iterate over each (i,j) & find the one which is having min value. Now, for finding this, I define 2 dp tables :

        dp1(i,j) : Max distance of a black cell from (i,j) considering all black cells with coloum no. < j.

        dp2(i,j) : Max distance of a black cell from (i,j) considering all black cells with coloum no. >= j.

        Now, let's try to build transition for dp1(i,j), it includes all black cells with coloum no. 0 to j-1. As per definition of dp1(i,j-1), it includes all black cells with coloum no. 0 to j-2.

        So, now dp1(i,j) = max(1 + dp1(i,j-1), max distance of a black cell in (j-1)th coloum from (i,j)).

        Similarly, dp2(i,j) = max(1 + dp2(i,j+1), max distance of a black cell in jth coloum from (i,j)).

        Now, max distance of a black cell from (i,j) = max(dp1(i,j), dp2(i,j)). You can check out my code : here

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    15 месяцев назад, # ^ |
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    Yaa. I do it with making 4 dp tables

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2 года назад, # |
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I was thinking of applying a greedy approach for problem C, why is it not enough to find the closest path from root to leaf or a node which has just 1 children. after we find the path length we can just get the answer by (N — (x + (x-1)) + 1 ( 1 for the case if the last node found had 1 child).

What i was thinking is for every step we have two choices either remove one branch or the other, when we remove one branch we also delete a node, thus (x + (x-1)), these are the nodes removed or infected, after that just subtract this from total N.

The approach is wrong but i can;t figure out why, can someone help please?

Okay, got the error, the approach was right, the problem was i was BFS so i had to take care of the fact that if there are two nodes in which one has only one child and there is other node which does not have a child, i will go with the one which does not have a child and in that case the formula will be n-(x+(x-1)) only

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    2 года назад, # ^ |
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    From what I understand you are trying to say, your approach is correct! This is actually the same approach that Geothermal had: https://codeforces.me/submissions/Geothermal You may have had some calculation error. Here is what he had to say:

    "Agreed. For anyone who isn't aware, the non-DP approach is to let v be the least deep vertex with at most one child. Then, the number of vertices that must be lost is d(v)+c(v)+1, where d(v) is the depth of v (where the root has depth 1) and c(v) is the number of children of v."

    (Why is the depth multiplied by 2 in your code?) "For each two-child vertex down which the virus spreads, you lose both the child onto which the virus spreads and the other child, which you must shut down to keep the virus from spreading onto the other branch."

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      2 года назад, # ^ |
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      and make sure you check for the path to a 0 child node as well.

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2 года назад, # |
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$$$O(n(log(max ai))^2)$$$ solution to E.

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2 года назад, # |
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For what purpose there was this limitation in A, that "no character is contained in both strings."?

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    2 года назад, # ^ |
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    If smallest character in s equals to smallest character in t, which should we choose?

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      2 года назад, # ^ |
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      Sorry, I still dont get it, what is wrong with this submission 160146764 ?

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        2 года назад, # ^ |
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        160162775 check this

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        2 года назад, # ^ |
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        If you take a character from string a, you are not resetting the count for the other string to 0.

        Assume given strings are a = "aaacdd" and b = "bcde", and k=10. Your vector ab will be then ["ddcaaa", "edcb"].

        Initially, your cnt = [0,0] and ans is empty. After first three iterations, ans becomes "aaa", cnt = [3,0], and ab = ["ddc", "edcb"]. Now in fourth iteration, ans becomes "aaab" but cnt = [3,1]. It should become [0,1].

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      2 года назад, # ^ |
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      Can you please check my solution if that condition is not included: comment link

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2 года назад, # |
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anyone plz discuss the approach of problem D. it will be very helpful for me, why it's maximize i+j and i-j, and , minimized i+j and i-j also.

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2 года назад, # |
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Not figuring out definitely correct (strict $$$O(nm)$$$ complexity) solution for D, but use some tricks to get it passed.

It is plausible to assume that $$$ans$$$ is close to the "center" of black cells (here I adopt $$$center=\frac{max-min}{2}$$$ for both x and y axis), then iterate over and move to adjacent cells util max Manhattan distance descend to optimum.

I'm not sure if max Manhattan distance has the same property of monotonicity as Euclidean distance (a classical problem is covering points on the plane with smallest circle). If that property holds, binary search may also work.

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    2 года назад, # ^ |
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    Yeah, I also thought of binary search, but the precomputation had to be done of diamond shapes of size k. Please share if you come across any such resources of doing the same.

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2 года назад, # |
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In problem C, can someone provide a smaller test case in which deleting the child with a higher subtree will lead to the wrong result? Thanks in advance!!

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    2 года назад, # ^ |
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    1

    7

    1 2

    1 3

    3 4

    3 5

    2 6

    6 7

    here root 1 : left child subtree (with root 2) has the same number of vertices that can be saved by

    right child subtree(with root 3).

    so if you cut left child subtree in the end answer will equal 2

    but if you cut right child subtree in the end will equal 3

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2 года назад, # |
Rev. 2   Проголосовать: нравится -15 Проголосовать: не нравится

The tests for A are very weak. I can see many solution hackable. I can't see the hack button. But here is the test case:

1
4 4 3
aaab
aaad

if this works swap the strings

1
4 4 3
aaad
aaab

Example: https://codeforces.me/contest/1689/submission/160093968 :

correct answer: aaaaaab,
output: aaaaaad

UPDATE: Almost every solution is hackable. Why I can't see hack button?

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2 года назад, # |
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1689E - ANDfinity can be optimized to $$$O(n A^2)$$$, where $$$A=\log{\max a_i}$$$
We can count $$$cnt[i][j]$$$ how many times pair of bits $$$i,j$$$ was in all $$$a_k$$$ it's works in $$$O(A^2)$$$ per element and then check if this grpah connected
To check if bit set just check $$$a[i][i] > 0$$$, if we have array $$$cnt$$$ DFS works in $$$O(A^2)$$$
So when we adding or subtracting 1 we can just update cnt we are doing it $$$O(n)$$$ times
code: 160147889

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2 года назад, # |
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Oh! Problem D had such simple solution. But I overkilled it with binary search.

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    2 года назад, # ^ |
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    Can you please explain how you used binary search I thought of doing so, searching for optimal distance but got dtucked on how to verify if the rhombus around all black points intersect at some pointfor current mid

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      2 года назад, # ^ |
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      There are four sides in rhombus. In all the cells of two opposite sides i + j remains the same and in all the cells in other two opposite sides i — j remains same where i and j are row and column number. So I divided them into two sets of ranges of two types where in first type, each range is of the form [i + j — mid, i + j + mid] and in other type, ranges are of form: [i — j — mid, i — j + mid]. Then just find the intersection of both type of ranges and iterate over every cell (i, j) to check if i + j lies in intersected range of first type of ranges and i — j lies in the intersected range of second type of ranges.

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2 года назад, # |
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dang I was really close with D, but I wrongly thought that 4 squares shouldn't be sufficient and end up making convex hull

B was too googlable, it was simply "minimum derangement" but overall the contest was nice!

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2 года назад, # |
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[DELETED]

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2 года назад, # |
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Can someone explain D please. I don't understand what 4 regions is getting created

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    2 года назад, # ^ |
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    The regions are top-left rectangle, top-right rectangle, bottom-left rectangle and bottom-right rectangle, which are created by lines parallel with coordinate axes passing through our yellow point.

    I'll add this in the editorial.

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2 года назад, # |
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in D, As per editorial, we are selecting 4 points with different cases. Now what if you find answer to a point which is not able to belong to the correct case. I mean case1 is for both positive but is not getting achieved. explain plz?

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2 года назад, # |
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Please tell me why my BFS code is not working on Prob C.

#include <bits/stdc++.h>
#include <ext/pb_ds/assoc_container.hpp>
#include <ext/pb_ds/tree_policy.hpp>

using namespace __gnu_pbds;
using namespace std;
using ll = long long;

#define all(a)             (a).begin(), (a).end()
#define rall(a)            (a).rbegin(), (a).rend()
#define sz(a)              (int) ((a).size())
#define pb                 push_back
#define fi                 first
#define se                 second
#define f0r(i, a, b)       for(int i = (a); i < (b); ++i)
#define f0rr(i, a, b)      for(int i = (a - 1); i >= (b); --i)
#define trav(i, v)         for(auto &i : (v))

template<class T> using V = vector<T>;
template<class T, class T1> using P = pair<T, T1>;
template<class T, class T1> using VP = vector<pair<T, T1>>;
template<class T> using Tree = tree<T, null_type, less<T>, rb_tree_tag,tree_order_statistics_node_update>;
template<typename T> T pow(T a, T b) { T res = 1; f0r(i, 0, b) res = res * a; return res; }
template<typename T> void ckmax(T &a, T b) { a = max(a, b);  }
template<typename T> void ckmin(T &a, T b) { a = min(a, b);  }

int dx4[] = {0, 1, 0, -1};
int dy4[] = {1, 0, -1, 0};
int dx8[] = {-1, -1, -1, 0, 1, 1, 1, 0};
int dy8[] = {-1, 0, 1, 1, 1, 0, -1, -1};

const ll linf = 1000000000000000000;
const int inf = 1000010000;
// <===================================================================================================>

vector<vector<int> > g;
vector<int> subTree, vis;

void dfs(int u) {
   vis[u] = 1;
   trav(v, g[u]) {
      if(vis[v]) continue;
      dfs(v);
      subTree[u] += subTree[v];
   }
   vis[u] = 0;
}

int main(){
   cin.tie(nullptr)->sync_with_stdio(false);

   int tt = 1;
   cin >> tt;
   f0r(T, 1, tt + 1) {
      int n;
      cin >> n;
      subTree.assign(n, 1);
      vis.assign(n, 0);
      g = vector<vector<int>> (n);
      f0r(i, 0, n - 1) {
         int u, v;
         cin >> u >> v;
         u--, v--;
         g[u].pb(v);
         g[v].pb(u);
      }
      dfs(0);
      int ans = 0;
      queue<int> que;
      que.push(0);
      while(true || !que.empty()) {
         int u = que.front();
         que.pop();
         vis[u] = 1;
         vector<int> ver;
         trav(i, g[u]) if(!vis[i]) ver.pb(i);
         if(sz(ver) == 0) break;
         if(sz(ver) == 1) {
            ans += (subTree[ver[0]] - 1);
            break;
         }
         if(subTree[ver[0]] > subTree[ver[1]]) {
            ans += (subTree[ver[0]] - 1);
            que.push(ver[1]);
         } else {
            ans += (subTree[ver[1]] - 1);
            que.push(ver[0]);
         }
      }
      cout << ans  << "\n";
   }
   return 0;
}

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2 года назад, # |
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Prob A is not diffcult, but cost me 48 minutes to solve it, becaue I add multi characters to string c in one operation. o(╥﹏╥)o

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2 года назад, # |
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Can someone tell me in 1689D - Lena and Matrix why taking average of leftmost and rightmost row and column (i.e. x=avg of(max row i+ min row i) and y=(max column j+ min column j) and taking all pssible value of (x,y) by taking ceil and floor value(i.e. 4 case) and checking which gives minimum distance for all black co0rdinates is giving wrong answer.(160145986). Any counter example to show this method is wrong??

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2 года назад, # |
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I have a doubt the code given for A gives wrong answer for

1

6 4 2

aaaaaa

aaaa

given_answer:aaaaaaaa

expected:aaaaa

I was thinking that we should also consider whether string a is small or stering b at a moment when both has same smallest character. Please correct me.

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    2 года назад, # ^ |
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    you have to stop when any of the string is empty and since "a" is lexographically smaller than "aa" so its better to empty the second string first to get optimal string

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      2 года назад, # ^ |
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      yaa exactly but many submissions including the editorial one gives the wrong answer as answer should be aaaaa. Correct me plz

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    2 года назад, # ^ |
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    Actually in given question same character does not appear in both strings. But lets say we allow same character to occur, then the answer in your case would be $$$aaaaaaaaa$$$ (9 times $$$a$$$)

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      2 года назад, # ^ |
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      Oh okay got it forgot to read that.

      Why the answer should be 9 times a we take 2 aa from string b then one a from string a and again 2 aa from string b. Now b is empty hence answer should be aaaaa.

      But yaa I have to read the problem more carefully

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2 года назад, # |
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The editorial's solution for problem D 1689D - Lena and Matrix may be too slow for languages like Python. I found a small speedup that allows Python code to pass the time limit.

Instead of "iterating over all squares in the matrix and finding the most distant black square", not all squares in the matrix actually need to be checked. For example, points outside the black diagonal rectangle (as shown in the editorial) clearly can't be optimal, and hence don't need to be checked.

Intuitively, points near the middle of the black diagonal rectangle have the best chance of being optimal and should be checked. I'm not sure how to prove that this is sufficient other than "Proof by AC" ;)

The time complexity is still O(nm) but maybe with a smaller constant factor.

Slow version, where all squares are checked (TLE in Python): https://codeforces.me/contest/1689/submission/160175658

Fast version, where only 4 middle squares are checked: https://codeforces.me/contest/1689/submission/160175205

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2 года назад, # |
Rev. 4   Проголосовать: нравится +3 Проголосовать: не нравится

A more complicated but mathematical(?) solution for D via direct analysis of manhattan distance.

First note that if any black square is between two other black squares in the same row or column then in the optimal configuration the longest distance will not be to that square. This can be shown by computing the manhattan distances to an arbitrary point directly. One of the squares on its left/right side will have greater distance. So removing those squares we have $$$O(n+m)$$$ black squares left.

Now fix some row $$$a.$$$ We find the optimal column(s) $$$b$$$ that minimize the distance for squares in this row. Thus, we want to minimize $$$\max ( |a-x_i| + |b-y_i| )$$$ for $$$b \in [1,m].$$$ Each of the $$$|a-x_i|$$$ are constants, so we have functions of the form $$$c + |x - d|.$$$ It's easy to see (by looking at the graphs) that the maximum of two such functions $$$\max(c_1 + |x - d_1|, c_2 + |x - d_2|)$$$ is another such function $$$c_3 + |x - d_3|.$$$ It follows that the function $$$f(b) = \max ( |a-x_i| + |b-y_i| )$$$ is bitonic, and we can binary search to find the optimal $$$b$$$ value(s) for this row.

Solution runs in $$$O(n^2 \log n)$$$ because for each of $$$n$$$ rows binary search takes $$$\log n$$$ and and each one we check we compute $$$O(n)$$$ numbers to find $$$f(b)$$$ at that column $$$b.$$$

163193116

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    2 года назад, # ^ |
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    not only can we binary search we can solve a system of equations to get exactly an x and y that will minimize the manhattan distance!

    this is done by noting that the maximum distance for a number of points would be max( a-xi + b-yi, xi-a + b-yi, a-xi + yi-b, xi-a + yi-b ) where i is the ith black square

    then we can see that we can compute the max manhattan distance is

    max( a+b + max(-xi-yi),

    b-a + max(xi+yi), 
    
     a-b + max(-xi+yi),
    
     -b-a + max(xi+yi))

    to minimize the maximum manhattan distance would be the equivalent of solving

    a+b + max(-xi-yi) = -b-a + max(xi+yi)

    b-a + max(xi-yi) = a-b + max(-xi+yi)

    though the problem with this is that a and b are not always integers

    in my submission i checked the four nearest integer points ¯_(ツ)_/¯ couldn't think of a better solution

    https://codeforces.me/contest/1689/submission/160184723

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2 года назад, # |
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In D, we are checking 4 points. But for each point we are checking, there should be 4 cases for signs. What if the points we have chosen can only make 3 sign cases and cannot make the 4th sign case. Explain please.

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    2 года назад, # ^ |
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    Even if we have just one B all 4 cases will be covered.

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      2 года назад, # ^ |
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      I mean while checking for a certain white element, the black which we considered giving maximum or minimum for (let's say) case 3(+-) is not being in case 3 with the current white we are checking.

      We take a black (2,3) with min i-j = -1 (case 3). When we are checking for white at (0,0) 0-2 = -2, 0-3 = -3, it belongs to case 4. So we should have chosen a different point which could have given a good case 3 with this point

      Actually the solution is correct and maybe it requires some extra proof. That's what I am asking

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2 года назад, # |
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Hehe finally got my O(nm + number of black points) solution for problem D to work :)

just in case of a harder problem in which n = 10e9, m = 10e9, and only the black points are given

https://codeforces.me/contest/1689/submission/160184723

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2 года назад, # |
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Can anyone explain why the maximum answer can be 2 for E?

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    2 года назад, # ^ |
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    maximum 2 operations after all the 0s have been turned into 1s

    for example

    1000

    0010

    0010

    =>

    1000

    1100

    1000

    the algorithm in general would be

    find maximum ai & -ai and two numbers that ai & -ai = max(ai & -ai)

    add 1 to one such number

    minus 1 from another one such number

    the minus 1 would become 11111110

    the add one would become 10000001

    since largest ai & -ai all other (ai & -ai) < max(ai & -ai) would be connected to 1111110

    then 10000001 would connect to all ai & -ai == max(ai & -ai)

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2 года назад, # |
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Can someone point out my mistake in C!? What I did is: At each level of BFS, I found the node with largest number of nodes in subtrees. Added that amount to result and continue BFS with rest nodes of that level. My Solution

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    2 года назад, # ^ |
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    Well, that does not work. The optimal solution is not to allways choose the bigger of the two subtrees. Instead, we have to choose the one where we can stop the infection at the earliest step. That is, where the path to the first vertex with less than two childs is shortest.

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2 года назад, # |
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For 1st problem I tried a test case 1 5 5 2 aabbc aabbd The correct answer for this should be aaaabbbbc, but even their solution is giving aaaabbbbd. If someone is getting correct answer please check by reversing the string order and please correct me if a I am going wrong somewhere.

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    2 года назад, # ^ |
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    The question stated: no [same] character is contained in both strings.

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2 года назад, # |
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Can we do D in O(K) where K denotes the number of black squares?

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2 года назад, # |
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I think there is an $$$O(n$$$ $$$log(max(a_i))$$$ $$$+$$$ $$$log^2(max(a_i)))$$$ solution for problem E. Details is as follows:

First of all, the current solution can be sped up to $$$O(n$$$ $$$log^2(max(a_i)))$$$ by using dynamic connectivity or creating a spanning tree which connects all the nodes for every $$$a_i$$$, updating it for every $$$+1$$$ or $$$-1$$$ operation and running DSU to check if the bits are connected. That way, the precomputation part will be $$$O(n$$$ $$$log(max(a_i)))$$$, and the checking part can be done in $$$O(log^2(max(a_i)))$$$.

For the second optimization, I claim that only checking $$$log(max(a_i))$$$ times is sufficient for us to determine whether there exists a construction for answer $$$=$$$ $$$1$$$.

First of all, we have to precompute the connectivity of the 30 bits in the given configuration (after adding $$$1$$$ to every $$$a_i$$$ $$$=$$$ $$$0$$$) using DSU. Then, we store the index of the LSB (least significant bit) of every connected component in a set (which I'll call $$$R$$$). To check answer = $$$0$$$ we simply have to check if $$$|R|$$$ $$$=$$$ $$$1$$$.

Lemma 1: $$$+1$$$ operations only work if $$$|R|$$$ $$$=$$$ $$$2$$$ and $$$min(R_i)$$$ $$$=$$$ $$$0$$$.

Proof of Lemma 1

Lemma 2: $$$-1$$$ operations only work when LSB of current value $$$\geq$$$ $$$max(R_i)$$$ and the current component doesn't disconnect after the operation.

Proof of Lemma 2

Lemma 3: We will find a solution after checking at most $$$log(max(a_i))$$$ distinct values that has LSB $$$\geq$$$ $$$max(R_i)$$$.

Proof of Lemma 3

Hence, we can find the answer with overall time complexity $$$O(n$$$ $$$log(max(a_i))$$$ $$$+$$$ $$$log^2(max(a_i)))$$$. The $$$O(n$$$ $$$log(max(a_i)))$$$ is from the precomputation for the graph, and $$$O(log^2(max(a_i)))$$$ is for the queries.

Here is my implementation of the above solution. If you spot any flaws in my solution, please comment below; I would very much appreciate it. Also, sorry for my bad English ._.

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2 года назад, # |
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Problem C can be solved using a simple preorder traversal, with only an adjacency list as extra memory. Essentially:

dfs(current, current_kill, &min_kill):
   if current has 0 child:
        min_kill = min(current_kill, min_kill);
   else if current has 1 child:
        min_kill = min(current_kill+1, min_kill);
   else:
        dfs(current.left, current_kill+2, min_kill);
        dfs(current.right, current_kill+2, min_kill); 

If the current node has no children, then the infection has reached it's end, and the current killed node count can be compared to the global min_kill count.

If the current node has one child, it can be stopped by pruning that one child. This ends the infection, and increases the kill count by 1 extra, so we compare current_kill+1 instead.

If the current node has 2 children, we will try pruning each child. This causes the child to die, and the other node to be infected, so dfs is called again with current_kill+2.

This strategy will explore every path that the infection can take and store the minimum killed nodes in a single variable.

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2 года назад, # |
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I tried the approach of Manhattan distance and rotating technique for problem D.Many people have solved this problem by DP. Can any one please explain your DP appraoch?

Thank you in advance for helping.

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2 года назад, # |
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n0sk1ll, How to prove the solution for B?

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2 года назад, # |
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Is there rigorous proof for question D?

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    14 месяцев назад, # ^ |
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    Go to CSES book -> Advanced Topics -> Geometry -> Distance Functions -> Rotating co-ordinates

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2 года назад, # |
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I have some questions about the solution to problem A. What if I have taken all the characters in string A but there is still more than k characters in string B?

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2 года назад, # |
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For problem E, there exists easier way to check if graph is connected.

Repeat $$$log$$$ $$$max$$$ $$$a_i$$$ times following :

  • If $$$a_0$$$ $$$\text &$$$ $$$a_i>0$$$ set $$$a_0$$$ to $$$a_0|a_i$$$

Finally if there exists some $$$a_i$$$ that $$$a_i$$$ $$$\text&$$$ $$$a_0=0$$$ then graph is disconnected.

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16 месяцев назад, # |
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In problem E, the check for connectivity can be done in $$$O(n \log{max(b_i)})$$$ in another way too:

Construct bipartite graph with one set of nodes corresponding to elements of the array, and one set of nodes corresponding to bits, edge exists between element $$$i$$$ and bit $$$x$$$ if $$$x$$$'th bit is set in $$$a_i$$$. Finally, just check this constructed graph.

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14 месяцев назад, # |
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In D you can just rotate co-ordinates in 45 Degress that makes stuff really easy

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    13 месяцев назад, # ^ |
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    Do you know why is taking leftmost, rightmost, top-most and bottom-most black points and taking their middle (4 ways at max) and then finding which one them gives minimum answer results in WA ?

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      13 месяцев назад, # ^ |
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      because in each of them you are considering either x or y never both of them

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        13 месяцев назад, # ^ |
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        Oh so you mean if we take that condition, there might be some cases where the sum of x,y will be greater than the condition we imposed since the conditions are independent on x and y whereas the one mentioned in editorial takes both x,y into account. Am I right in understanding ?

        Thanks for the help.

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11 месяцев назад, # |
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Testcases for A are weak. https://codeforces.me/contest/1689/submission/238293004 In this submission the output for 1 2 1 2 ab a The output of code-aa Actual output-a I'm not sure if the testcases can be changed now but just noticed the error so thought I should comment it.

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3 месяца назад, # |
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C can be solved using PostOrder traversal. DP is overkill.

My implementation: 278017190