This is an *O(nklogn)* solution where *n* is the length of the input array and *k* is the size of the increasing sub-sequences. It is based on the solution mentioned in the question.

`vector<int> values`

, an *n* length array, is the array to be searched for increasing sub-sequences.

```
vector<int> temp(n); // Array for sorting
map<int, int> mapIndex; // This will translate from the value in index to the 1-based count of values less than it
partial_sort_copy(values.cbegin(), values.cend(), temp.begin(), temp.end());
for(auto i = 0; i < n; ++i){
mapIndex.insert(make_pair(temp[i], i + 1)); // insert will only allow each number to be added to the map the first time
}
```

`mapIndex`

now contains a ranking of all numbers in `values`

.

```
vector<vector<int>> binaryIndexTree(k, vector<int>(n)); // A 2D binary index tree with depth k
auto result = 0;
for(auto it = values.cbegin(); it != values.cend(); ++it){
auto rank = mapIndex[*it];
auto value = 1; // Number of sequences to be added to this rank and all subsequent ranks
update(rank, value, binaryIndexTree[0]); // Populate the binary index tree for sub-sequences of length 1
for(auto i = 1; i < k; ++i){ // Itterate over all sub-sequence lengths 2 - k
value = getValue(rank - 1, binaryIndexTree[i - 1]); // Retrieve all possible shorter sub-sequences of lesser or equal rank
update(rank, value, binaryIndexTree[i]); // Update the binary index tree for sub sequences of this length
}
result += value; // Add the possible sub-sequences of length k for this rank
}
```

After placing all *n* elements of `values`

into all *k* dimensions of `binaryIndexTree`

. The `value`

s collected into `result`

represent the total number of increasing sub-sequences of length *k*.

The binary index tree functions used to obtain this result are:

```
void update(int rank, int increment, vector<int>& binaryIndexTree)
{
while (rank < binaryIndexTree.size()) { // Increment the current rank and all higher ranks
binaryIndexTree[rank - 1] += increment;
rank += (rank & -rank);
}
}
int getValue(int rank, const vector<int>& binaryIndexTree)
{
auto result = 0;
while (rank > 0) { // Search the current rank and all lower ranks
result += binaryIndexTree[rank - 1]; // Sum any value found into result
rank -= (rank & -rank);
}
return result;
}
```

The binary index tree is obviously *O(nklogn)*, but it is the ability to sequentially fill it out that creates the possibility of using it for a solution.

`mapIndex`

creates a rank for each number in `values`

, such that the smallest number in `values`

has a rank of 1. (For example if `values`

is "2, 3, 4, 3, 4, 1" then `mapIndex`

will contain: "{1, 1}, {2, 2}, {3, 3}, {4, 5}". Note that "4" has a rank of "5" because there are 2 "3"s in `values`

`binaryIndexTree`

has *k* different trees, level *x* would represent the total number of increasing sub-strings that can be formed of length *x*. Any number in `values`

can create a sub-string of length 1, so each element will increment it's rank and all ranks above it by 1.

At higher levels an increasing sub-string depends on there already being a sub-string available of a shorter length and lower rank.

Because elements are inserted into binary index tree according to their order in `values`

, the order of occurrence in `values`

is preserved, so if an element has been inserted in `binaryIndexTree`

that is because it preceded the current element in `values`

.

An excellent description of how binary index tree is available here: http://www.geeksforgeeks.org/binary-indexed-tree-or-fenwick-tree-2/

You can find an executable version of the code here: http://ideone.com/GdF0me