# not able to understand a dp solution

The problem is as follows:

Lazer Tag consists of a group play, where you are assigned a fixed number of bullets (popularly known as Laser shots) during the whole game. Each right shoot on your target enemy, gives you one point.

Consider the series of your hits and misses which can be represented in the form of “x” and “o” where “o” represents a hit and “x” represents a miss. Suppose the series is of the form “xxxoooxxxxooxxo”, then your final score will be equal to `3^2 + 2^2 +1^2` i.e add up the squares of every maximal number of consecutive hits in the entire game play.

The probability of hitting the jth shot correctly (1≤j≤n) is P(j). In simpler terms, the probability of getting an “o” in the series at jth turn is P(j). You need to calculate the expected score at the end of your round.

I can understand a O(n^2) solution of this using memoization but the question requires a O(n) solution. I have seen the O(n) solution but I am not able to understand it. The O(n) solution is as follows:

``````for(i = 1; i <= n; i++)
dp[i] = (dp[i-1] + p[i-1]) * p[i];
for(i = 1; i <= n; i++)
ans+=2 * dp[i] + p[i];
``````

where p[i] is the prob of hitting ith target. Can anyone explain how the O(n) solution works?

• The solution you posted is not correct. That might be part of why you are having trouble understanding it. Just run a simulation of it, averaging your random results a few million times and you'll see it gives a different result. – Chill Oct 30 '13 at 17:26
• @Chill the solution is correct. This is the problem link [codechef.com/TCFST13/problems/TCFST05/] and the solution i have given is one of the accepted ones – SHB Oct 30 '13 at 17:35
• There must be something wrong with my simulation then. Check it out and let me know if you see any problems. pastebin.com/NHWgK1fZ – Chill Oct 30 '13 at 17:41
• `“o” represents a hit and “x” represents a miss` WHY??? – j_random_hacker Oct 30 '13 at 19:30
• @user2094963: It wasn't a serious comment. All I meant was that 99% of the time, "X" means "hit" and "O" means "miss". It would be like if the question talked about a traffic light that used red to indicate "go" and green to indicate "stop" :-P – j_random_hacker Oct 30 '13 at 20:19

You can think of the scoring in the following way:

1. 1 point for each hit
2. 2 points for EVERY run of hits of length >1 (scoring overlapping runs multiple times)

For example, a sequence of xxooox would score:

1. +1 for each of the o's
2. +2 for ooo
3. +2 for first oo
4. +2 for second oo

Score = 1*3+2*3 = 3+6 = 9 points. (This matches the original way of score because 9=3*3)

dp[i] computes the expected number of runs of length >1 that end at position i.

So to compute the total expected score we need to sum 2*dp[i] (as we get 2 points for every run), plus the sum of p[i] to add the expected score from getting 1 point for each hit.

The recurrence relation is because the expected number of runs of length >1 ending at position i will be:

1. +1 if we have a new run starting at position i by getting a hit at i and i-1 (probability p[i]*p[i-1])
2. +dp[i-1] if we continue the runs ending at position i-1 by getting another hit (probability p[i])
• could u explain how u came up with the scoring technique i.e 1 for each o, +2 for ooo .... .i am new to dp and wanted to know how to approach such ques – SHB Oct 30 '13 at 20:17
• Very insightful Peter, I'd love to know how you noticed that! – j_random_hacker Oct 30 '13 at 20:18
• I think this is more of a mathematical thing than a common DP technique. (I think I might have seen something similar in some Project Euler problem once upon a time.) – Peter de Rivaz Oct 30 '13 at 20:47
• @user2094963 the insight is much more about computing a quadratic function in a weird way that is amendable to a probabilistic recurrence. it's definitely cool and clever solution to this particular problem, but you don't need to understand it to solve DP problems generally. – Rob Neuhaus Oct 30 '13 at 20:59
• @rrenaud can this problem be solved in any other way in O(n) time? – SHB Oct 30 '13 at 21:04