`Log(N)`

per query - `Mlog(N)`

in total solution exists. Preprocessing - `Nlog(N)`

{binary uplifting} + `NloglogN`

{Sieve of Eratosthenes } = `NloglogN`

;

I would write here hints in order to encourage you to do some research)

1) Unexpected start. Number of prime numbers less than N is ~N/ln(N). So 100.000-th prime is slightly greater than 1.000.000. Indeed, googling showed me that 100.000-th prime is 1.299.709. Perform Sieve of Eratosthenes until 1.299.709 and store all primes in one separate array in the increasing order.

2) Replace each assigned number to prime in the following manner - 1 is 1-st prime, 2 is the second and i is i-th prime. Assignment can be done in O(1) - `getPrime(int assignedNumber`

) returns `primes[assignedNumber]`

3) Modify Binary uplifting method. The key idea is storing for each vertex `V`

array of 1-st parent, 2-nd, 4-th, 8-th and so on. Usually `parents[v][i]`

stores parent of `V`

which is `2^i`

levels higher than `V`

. Computation of such array is Nlog(N). In my approach I suggest `parents[v][i]`

**stores NOT a parent BUT multiplication** of all primes from V to 2^i-th parent.

4) Also run `DFS`

from any vertex, say 1 and store distances from 1 to all other vertices in `distances[n]`

. This is useful for fast computing distance between **any 2 vertices**.

5) Answering the query -

If a is a parent of b or vice-versa find distance between a and b : `dist = distance[child_vertex]-distance[parent_vertex]`

; Go up from child to parent with binary steps and compute multiplication of primes **modulo getPrime(C)** where C is the query parameter. **If answer is 0 type find either not find**.

If nor a parent of b nor b parent of a, find c = LCA(a,b). Repeat previous method for (a,c) and (b,c).

**UPDATE:** Please, note that we are avoiding integer overflow taking by modulo on each step of uplifting. I forgot to say that you you also should store parents itself. So 2 main arrays with `size = NlogN`

parents and multiplications by modulo. When I said find distance between v1 and v2 ang perform uplifting I meant something like that:

```
go_up_from_vertex(int vertex,int dist)
{
int deg=0;
int mul = 1;
while(dist>0){
if(dist%2==1)
{
mul*= multiplication[vertex][deg];
mul%=primes[queryC];
//"accumulate" primes product on the path from vertex to 2^deg-th parent
vertex = parents[vertex][deg];
// we've just jumped upstairs. current vertex should be changed.
}
deg++;
dist/=2;
}
}
```

**UPDATE 2** As the author of the question mentioned, my approach doesn't work for multiple C - actually, when we compute values of the `mulpiplication[v][i]`

array we have to perform calculations by modulo. But this array must be prepared before answering queries, so we just can't decide which modulo should be choosen for modular calculations. But we can **compute answer modulo 2,3,5,7,11,13,17** and **be able to find answer modulo any number <=2*3*5*...*17 = 510510** using Chinese remainder theorem. Of course complexity multiplied to the complexity of solving system of modular equations - O(base primes count)^2 = 49.

I found chinese remainder theorem usage for modular equations only in russian -translation. something in English. But it looks like too complex approach)) Try to implement my approach only if you want to improve your number theory skills)

My be modification of Heavy-Light decomposition will work here. I can't say exactly but description (again translation from russian) promises nice results)