typo in D. (n-1)*n/2

Problem A Challenge: Assume, that you can substract a prime from x at most 3 times.

I couldn't understand the explanation of problem C. Can someone describe it?

In problem D is tagged as DP .Can some one tell the method to solve it using DP ? We can calculate bad strings using 4 different for loops (corresponding to type of bad string) , any other method to do that with less typing ?

For problem D, how can there be only 4 patterns? For example the string $$$ABBAB$$$ is also a bad string but its pattern is not the same as the 4 given patterns.

Constraints are really deceiving in E. Could somebody explain an O($$$a*2^a$$$) solution?

In Problem D, I'm having trouble counting the number of such substrings. I read a lot of different codes but I don't seem to get it. Can somebody please explain their own method to me? Thanks a lot in advance.

A proof for why the greedy algorithm works in $$$C$$$:

First note that for any $$$v>1$$$, you have to stand on at least $$$v$$$ or $$$v-1$$$, because if you didn't stand on both this means that you descended from $$$a>v$$$ to $$$b<v-1$$$, which means you are dead.

You are initially standing at $$$h$$$, assume you will walk without any crystals until you first reach that $$$x>2$$$ where $$$x-1$$$ is moved out and $$$x-2$$$ is hidden. Now you must use at least $$$1$$$ crystal to continue. You can use it either to:

1. move out the platform at $$$x-2$$$, then descend to it directly.
2. hide the one at $$$x-1$$$ and move to it, where you will still have the opportunity to continue to $$$x-2$$$ without extra crystals, so this option is better.

The other scenario you can follow starting from $$$h$$$, is that which would end on $$$x-1$$$ (without going to $$$x$$$), and this scenario will cost at least $$$1$$$ crystal. So we deduce that the best option is option $$$2$$$ in the previous scenario. Starting from $$$x-1$$$, you can continue to use the same followed logic starting from $$$h$$$.

in problem E, when iterating to new character x then how we calculate dp[mask|(1<<x)] ?

I have tried an O(m^2*2^m) solution for problem E but it is giving TLE.

I cannot understand the solution of problem E. Specially, **" If letter y is already on current keyboard, then we should add to answer cntx,y(posx−posy), and cntx,y(posy−posx) otherwise" **sentence. Why should we consider abount the letter which is not included in the keyboard?

I cannot understand the solution of problem E. Specially, "If letter y is already on current keyboard, then we should add to answer cntx,y(posx−posy), and cntx,y(posy−posx) otherwise" sentence. Why should we consider the letter y which is not included in the keyboard? And on last formula,∑y∈msk(cntx,yposx)−∑y∉msk(cntx,yposx), why there is no posy? Where do they go?

I cannot understand the solution of problem E. Specially, "If letter y is already on current keyboard, then we should add to answer cntx,y(posx−posy), and cntx,y(posy−posx) otherwise" sentence. Why should we consider the letter y which is not included in the keyboard? And on last formula,∑y∈msk(cntx,yposx)−∑y∉msk(cntx,yposx), why there is no posy? Where do they go?

Can any one explain how to solve D if there are 26 character?

Can someone explain how to solve D with 'binary search'?

How to solve D using DP?

Just a side fact: The resultant tree that gets formed in the problem F is also called Caterpillar Tree.

can someone please explain the structure of tree formed in problem F? I didn't get it from editorial completely.

Why is there a "Binary Search" Tag on Problem D? How to solve it using Binary Search?

How to understand the meaning of the dp array in E problem?

Problem fixed.

Sorry for inconvenience.

awoo, in problem E, could you explain how you arrived at the final formula

Can Someone Explain What d[M][N] represents and how we used it to calculate dp[M] in the editorial for problem E?

Can someone please share some way to actually count the number of good substrings(not negating bad substrings), just curious!!

Doubt in problem E.

Hi, i have a question about why my code didn't get TLE.

My idea:

Imagine the graph with letters as nodes and weighted edges (the weight of an edge is how many times the node u came right before node v or node v came right before node u in the string).

I used the fact that |a-b| = max( a,b ) — min( a,b ).

So i started selecting the letter (or node) with the position $$$N$$$, the the letter with position $$$N-1$$$ and so on, obviously taking care not using a node twice. And with this in mind a node $$$u$$$ will add (its postion) times (the sum of the edges from that node to the rest of the nodes that have not been selected yet) — (its position) times (the sum of the edges from that node to the rest of the nodes that have been selected ).

I did this but i think that the complexity is m^3 * 2^m which is somethig like 8*10^9 worst case.

Could someone explain me why this solution passed?

My code: 62655475

In problem D, what is the role of x in res-=cur-x. For the first iteration of the loop we check for strings that end with AAB or BBA. And for the second iteration we check for strings that start with ABB or BBA. Why subtract x=1 from res ? Got it.

Can someone please explain the intuition behind problem E and can anyone please give some tips to improve bitmasking.

Random solution to problem F gives ACC, is it because test cases are weak? 63616653 I just choose 20 nodes at random plus the center(s) of the tree, and for each of them run the same dfs assuming that answer pass through it. Can someone tell the probability of choosing a vertex and it belongs to an answer? I know it's something like ANSWER / N.

would someone plz answer my question ??

In problem B, tutorial's time complexity is O(n * logn) in every query. so i think total time complexity of the algorithm is O(q * n * logn).

https://codeforces.com/contest/1238/submission/64450447 — this is my code. my time complexity is O(n+log n) ~ O(n) in every query. so i think total time complexity of my algorithm is O(q*n).

my question is why the tutorial's code passed but mine couldn't passed?

wait, in problem B if the complexity in each query is O(n log n) then does that mean the whole problem will be O(q*n*logn), how does this still work with q <= 1e5?

Can anyone tell me why am i getting TLE in B ?
Do read the blog first .
Because the reason behind TLE is strange link to the blog is here...

Constraints on E is unecessarily too tight, usage of long long gives TLE

Educational Forces = Diagonal Pattern,chess pattern,snake pattern or some random string pattern