First observation: `solve`

calls `doFunc`

, but not the other way around. Therefore, the complexity of `solve`

will depend on the complexity of `doFunc`

, but not the other way around. We need to figure out the complexity of `doFunc`

first.

Let `T(E, D, N)`

be the time complexity of `doFunc`

as a function of `E`

, `D`

and the number of elements `N`

in the list. Every time `doFunc`

is called, we do `N`

iterations of the loop and then invoke `doFunc`

with `E+1`

, `D-1`

, and the list unchanged. Based on this, we know that the time complexity of `doFunc`

is given by the following recursive formula:

`T(E, D, N) = aN + b + T(E+1, D-1, N)`

Here, `a`

and `b`

are some constants to be determined.

Now we need a base case for this recursive formula. Our base case, the only time we don't recurse, is when `D <= 0`

. Assuming that `D`

is non-negative, this means `D = 0`

is the base case. We get the following additional requirement:

`T(E, 0, N) = c`

Here, `c`

is some constant to be determined.

Putting this all together, we can list out a few values for different values of `D`

and see if we can identify a pattern:

```
D T(E, D, N)
0 c
1 c + b + aN
2 c + 2b + 2aN
3 c + 3b + 3aN
...
k c + kb + kaN
```

Based on this, we can guess that `T(E, D, N) = c + Db + aDN`

for some constants `a, b, c`

. We can see that this formula satisfies the base case and we can check that it also satisfies the recursive part (try this). Therefore, this is our function.

Assuming `E`

, `D`

and `N`

are all independent and vary freely, the time complexity of `doFunc`

is best rendered as `O(c + Db + aDN) = O(DN)`

.

Since `solve`

calls `doFunc`

once for each element in the list, its complexity is simply `N`

times that of `doFunc`

, i.e., `O(DN^2)`

.