Assume the final result will be in an integer R. You should scan from left to right on the string Then, you should keep a stack Z, and update it as you scan from left to right.

You should initially push a 0 onto Z. When you encounter a '(' at index i, you should push 0 onto S. When you encounter a ')' at index i, you should increment R by (T * (T+1) / 2), T being the top element of Z. Then you should pop T, and increment **the new top element** by 1.

Once the scan is complete, you should increment R for one more time by (T * (T+1) / 2), as there is still an element T in Z that we initially put.

The scan using the stack Z should take **linear time**. Below is a not-so-efficient Python implementation that is hopefully easy to understand.

```
def solve(s):
R = 0
Z = [0]
for i in range(0, len(s)):
if s[i] == '(':
Z.append(0)
else:
R += Z[-1] * (Z[-1] + 1) / 2
Z = Z[:-1]
Z[-1] += 1
R += Z[-1] * (Z[-1] + 1) / 2
return R
```

The idea behind the incrementing R is as follows. Basically you keep the number of the **consecutive** same-level balanced strings until are about to get out of that level. Then, when you are about to go to a higher level(i.e. when we **know** there won't be any other same-level and consecutive substring, we update the solution.

The value of T * (T + 1) / 2 can be understood if you think about the intervals a bit differently. Let's enumerate those consecutive same-level balanced substrings from 1 to T. Now, picking a balanced substrings using these is basically picking a starting and ending point for our larger substring. If we pick substring #1 as our starting point, there are T other substrings we may pick as the ending point. For #2, there are (T-1), and so on. Basically there are T*(T+1)/2 different intervals we can pick as a valid balanged substring, which is why we increment R by that value.

The final increment operation we apply to R is just to not omit the outermost level.