Let:

```
dp[i, j] = number of increasing subsequences of length j that end at i
```

An easy solution is in `O(n^2 * k)`

:

```
for i = 1 to n do
dp[i, 1] = 1
for i = 1 to n do
for j = 1 to i - 1 do
if array[i] > array[j]
for p = 2 to k do
dp[i, p] += dp[j, p - 1]
```

The answer is `dp[1, k] + dp[2, k] + ... + dp[n, k]`

.

Now, this works, but it is inefficient for your given constraints, since `n`

can go up to `10000`

. `k`

is small enough, so we should try to find a way to get rid of an `n`

.

Let's try another approach. We also have `S`

- the upper bound on the values in our array. Let's try to find an algorithm in relation to this.

```
dp[i, j] = same as before
num[i] = how many subsequences that end with i (element, not index this time)
have a certain length
for i = 1 to n do
dp[i, 1] = 1
for p = 2 to k do // for each length this time
num = {0}
for i = 2 to n do
// note: dp[1, p > 1] = 0
// how many that end with the previous element
// have length p - 1
num[ array[i - 1] ] += dp[i - 1, p - 1]
// append the current element to all those smaller than it
// that end an increasing subsequence of length p - 1,
// creating an increasing subsequence of length p
for j = 1 to array[i] - 1 do
dp[i, p] += num[j]
```

This has complexity `O(n * k * S)`

, but we can reduce it to `O(n * k * log S)`

quite easily. All we need is a data structure that lets us efficiently sum and update elements in a range: segment trees, binary indexed trees etc.