# Leetcode House robber

I was trying House Robber problem(dp problem) on leet code. This solution from one of the user GYX looks simple and elegant.

``````   int rob(vector<int>& num) {
int n = num.size();
if (n==0) return 0;
vector<int> result(n+1,0);
result[1] = num[0];
for (int i=2;i<=n;i++){
result[i] = max(result[i-1],result[i-2]+num[i-1]);
}
return result[n];
}
``````

But I just could not get my head around the logic. Please help me with the logic and also how to approach problems like this?

Suppose I store the amount in kth house in `house[k]`.

Suppose now I store the maximum amount of money possible to loot from the first k houses(and first k only) in `max[k]`.

Now consider no houses, so `max[0]=0`

Now considering only first house, `max[1]`=amount in house 1

Now considering first 2 houses,

`max[2]`={either `max[1]`(implies we chose to loot house 1) or (amount in house 2 + maximum amount that I had looted until the house located 2 places before my current house)}=`{max(max[1],house[2]+max[0])}`

Similarly for first 3 houses, `max[3]=max(max[2],house[3]+max[1])`

Observing this trend, it can be formulated that `max[k]=max(max[k-1],house[k]+max[k-2])`. This value is calculated till in the end when there are no more houses, we get the maximum amount that can be looted from these first n houses.

DP problems strike the head only when you have had some practice and familiarity before, and this always helps.

Basically the answer is `f(n) = max( f(n-1), f(n-2) + arr[n] )` and you are asking why.

Let's suppose this array `arr = [9,1,7,9]` and `f(n)` is the function.

When the array is only `[9]`, your max `f(0)` will be `arr[0]`.

When the array is `[9,1]`, your max `f(1)` is `max(arr[0], arr[1])`.

When the array is `[9,1,7]`, if you select `7`, you can't select `1` therefore `f(n-2) + arr[n]`. However, if you don't select `7`, you max `f(2)` will be same as `f(1)` which is `f(n-1)`.

When the array is `[9,1,7,9]`, you need to drop both 1 & 7 and choose 9, 9. `f(n) = max( f(n-1), f(n-2)+arr[n] )` equation satisfies this case.

Take a look at this simple recursive code. Visulizing a problem solved in DP is hard at first glance. You should always work your way up to that from a low performant recursive code first. Here is a different version of the code:

``````p = [0, 1, 2, 3, 1, 2, 3, 1, 2, 5, 8, 2]
def R(i):
if i == 1 or i == 2:
return i
else:
return max(p[i] + R(i - 2), R(i - 1))

print(R(11))
``````

This is also easily memoizable if you want to bring the efficiency up.