**Problem:**

You are given a rooted tree where each node is numbered from 1 to N. Initially each node contains some positive value, say `X`

. Now we are to perform two type of operations on the tree. Total `100000`

operation.

**First Type:**

Given a node

ndand a positive integerV, you need to decrease the value of all the nodes by some amount. If a node is at a distance ofdfrom the given node then decrease its value byfloor[v/(2^d)]. Do this for all the nodes.

That means value of nodendwill be decreased byV(i.e, floor[V/2^0]). Values of its nearest neighbours will be decreased byfloor[V/2]. And so on.

**Second Type:**

You are given a node

nd. You have to tell the number of nodes in the subtree rooted atndwhose value is positive.

** Note: **Number of nodes in the tree may be upto `100000`

and the initial values, `X`

, in the nodes may be upto `1000000000`

. But the value of **V** by which the the decrement operation is to performed will be at most `100000`

.

How can this be done efficiently? I am stuck with this problem for many days. Any help is appreciated.

My Idea : I am thinking to solve this problem offline. I will store all the queries first. then, if somehow I can find the time[After which operation] when some node **nd**'s value becomes less than or equal to zero(say it `death time`

, for each and every node. Then we can do some kind of binary search (probably using Binary Indexed Trees/ Segment Trees) to answer all the queries of second type. But the problem is I am unable to find the `death time`

for each node.

Also I have tried to solve it online using **Heavy Light Decomposition** but I am unable to solve it using it either.

Thanks!

`v/2^1`

its grandchildren (child nodes' children) by`v/2^2`

, etc.? – Jim Mischel Apr 11 '14 at 4:06