This is a classical dynamic programming problem (and not typically solved using regular expressions).

*My naive implementation (count the 3's for each 2 after each 1) has been running for an hour and it's not done.*

That would be an exhaustive search approach which runs in exponential time. (I'm surprised it runs for hours though).

Here's a suggestion for a dynamic programming solution:

## Outline for a recursive solution:

(Apologies for the long description, but each step is really simple so bear with me ;-)

If the **subsequence** is empty a match is found (no digits left to match!) and we return 1

If the **input sequence** is empty we've depleted our digits and can't possibly find a match thus we return 0

(Neither the sequence nor the subsequence are empty.)

(Assume that "*abcdef*" denotes the input sequence, and "*xyz*" denotes the subsequence.)

Set `result`

to 0

Add to the `result`

the number of matches for *bcdef* and *xyz* (i.e., discard the first input digit and recurse)

If the first two digits match, i.e., *a* = *x*

- Add to the
`result`

the number of matches for *bcdef* and *yz* (i.e., match the first subsequence digit and recurse on the remaining subsequence digits)

Return `result`

# Example

Here's an illustration of the recursive calls for input 1221 / **12**. (Subsequence in bold font, · represents empty string.)

# Dynamic programming

If implemented naively, some (sub-)problems are solved multiple times (· / 2 for instance in the illustration above). Dynamic programming avoids such redundant computations by remembering the results from previously solved subproblems (usually in a lookup table).

In this particular case we set up a table with

- [length of sequence + 1] rows, and
- [length of subsequence + 1] columns:

The idea is that we should fill in the number of matches for 221 / **2** in the corresponding row / column. Once done, we should have the final solution in cell 1221 / **12**.

We start populating the table with what we know immediately (the "base cases"):

- When no subsequence digits are left, we have 1 complete match:

We then proceed by populating the table top-down / left-to-right according to the following rule:

In cell [*row*][*col*] write the value found at [*row*-1][col].

Intuitively this means *"The number of matches for 221 / ***2** includes all the matches for 21 / **2**."

If sequence at row *row* and subseq at column *col* start with the same digit, add the value found at [*row*-1][*col*-1] to the value just written to [*row*][*col*].

Intuitively this means *"The number of matches for 1221 / ***12** also includes all the matches for 221 / **12**."

The final result looks as follows:

and the value at the bottom right cell is indeed 2.

# In Code

Not in Python, (my apologies).

```
class SubseqCounter {
String seq, subseq;
int[][] tbl;
public SubseqCounter(String seq, String subseq) {
this.seq = seq;
this.subseq = subseq;
}
public int countMatches() {
tbl = new int[seq.length() + 1][subseq.length() + 1];
for (int row = 0; row < tbl.length; row++)
for (int col = 0; col < tbl[row].length; col++)
tbl[row][col] = countMatchesFor(row, col);
return tbl[seq.length()][subseq.length()];
}
private int countMatchesFor(int seqDigitsLeft, int subseqDigitsLeft) {
if (subseqDigitsLeft == 0)
return 1;
if (seqDigitsLeft == 0)
return 0;
char currSeqDigit = seq.charAt(seq.length()-seqDigitsLeft);
char currSubseqDigit = subseq.charAt(subseq.length()-subseqDigitsLeft);
int result = 0;
if (currSeqDigit == currSubseqDigit)
result += tbl[seqDigitsLeft - 1][subseqDigitsLeft - 1];
result += tbl[seqDigitsLeft - 1][subseqDigitsLeft];
return result;
}
}
```

# Complexity

A bonus for this "fill-in-the-table" approach is that it is trivial to figure out complexity. A constant amount of work is done for each cell, and we have length-of-sequence rows and length-of-subsequence columns. Complexity is therefor *O(MN)* where *M* and *N* denote the lengths of the sequences.