# Find the number of occurrences of a subsequence in a string

For example, let the string be the first 10 digits of pi, 3141592653, and the subsequence be 123. Note that the sequence occurs twice:

3141592653
1    2  3
1  2  3

This was an interview question that I couldn't answer and I can't think of an efficient algorithm and it's bugging me. I feel like it should be possible to do with a simple regex, but ones like 1.*2.*3 don't return every subsequence. My naive implementation in Python (count the 3's for each 2 after each 1) has been running for an hour and it's not done.

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Please specify the programming language you're using regex with. – Matt Ball Jul 29 '11 at 18:15
Python. I've edited the question. – Jake Jul 29 '11 at 18:19

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:

• When no sequence digits are left, we can't have any matches:

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.

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@Jake, you could easily strip all characters that aren't 1's 2's or 3's from your search before your loops. You can also strip all characters before the first 1 and after the last 3, to reduce the problem string to '1123' which shouldn't take long to loop through – Paulpro Jul 29 '11 at 18:36
Is it possible to make O(N) solution, where N is equal to length of string? – Luka Rahne Jul 31 '11 at 10:19
Excellent explanation! – Bart Kiers Aug 1 '11 at 8:30
@aioobe, Wow, this is an amazing answer. Thanks so much! – Jake Aug 1 '11 at 15:05
Excellent answer! I especially appreciate the illustrations! – Dream Lane Aug 3 '12 at 3:59

# straightforward, naïve solution; too slow!

def num_subsequences(seq, sub):
if not sub:
return 1
elif not seq:
return 0
result = num_subsequences(seq[1:], sub)
if seq[0] == sub[0]:
result += num_subsequences(seq[1:], sub[1:])
return result

# top-down solution using explicit memoization

def num_subsequences(seq, sub):
m, n, cache = len(seq), len(sub), {}
def count(i, j):
if j == n:
return 1
elif i == m:
return 0
k = (i, j)
if k not in cache:
cache[k] = count(i+1, j) + (count(i+1, j+1) if seq[i] == sub[j] else 0)
return cache[k]
return count(0, 0)

# top-down solution using the lru_cache decorator
# available from functools in python >= 3.2

from functools import lru_cache

def num_subsequences(seq, sub):
m, n = len(seq), len(sub)
@lru_cache(maxsize=None)
def count(i, j):
if j == n:
return 1
elif i == m:
return 0
return count(i+1, j) + (count(i+1, j+1) if seq[i] == sub[j] else 0)
return count(0, 0)

# bottom-up, dynamic programming solution using a lookup table

def num_subsequences(seq, sub):
m, n = len(seq)+1, len(sub)+1
table = [[0]*n for i in xrange(m)]
def count(iseq, isub):
if not isub:
return 1
elif not iseq:
return 0
return (table[iseq-1][isub] +
(table[iseq-1][isub-1] if seq[m-iseq-1] == sub[n-isub-1] else 0))
for row in xrange(m):
for col in xrange(n):
table[row][col] = count(row, col)
return table[m-1][n-1]

# bottom-up, dynamic programming solution using a single array

def num_subsequences(seq, sub):
m, n = len(seq), len(sub)
table = [0] * n
for i in xrange(m):
previous = 1
for j in xrange(n):
current = table[j]
if seq[i] == sub[j]:
table[j] += previous
previous = current
return table[n-1] if n else 1
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+1 for the last variant. Very simple and efficient. – Markus Jarderot Sep 25 '11 at 13:06

One way to do it would be with two lists. Call them Ones and OneTwos.

Go through the string, character by character.

• Whenever you see the digit 1, make an entry in the Ones list.
• Whenever you see the digit 2, go through the Ones list and add an entry to the OneTwos list.
• Whenever you see the digit 3, go through the OneTwos list and output a 123.

In the general case that algorithm will be very fast, since it's a single pass through the string and multiple passes through what will normally be much smaller lists. Pathological cases will kill it, though. Imagine a string like 111111222222333333, but with each digit repeated hundreds of times.

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What's the complexity? Sounds to me that it is exponential, no? – aioobe Aug 1 '11 at 13:56
I think it approaches N^2, but it can't be worse than that. In the worst case, every character read would require traversing a list that's as long as the number of characters previously read. – Jim Mischel Aug 1 '11 at 22:26
This is the same Dynamic Programming algorithm and has complexity = O((# char in sequence)*(# char in string)) – gabber12 Mar 8 '15 at 10:38
from functools import lru_cache

def subseqsearch(string,substr):
substrset=set(substr)
#fixs has only element in substr
fixs = [i for i in string if i in substrset]
@lru_cache(maxsize=None) #memoisation decorator applyed to recs()
def recs(fi=0,si=0):
if si >= len(substr):
return 1
r=0
for i in range(fi,len(fixs)):
if substr[si] == fixs[i]:
r+=recs(i+1,si+1)
return r
return recs()

#test
from functools import reduce
def flat(i) : return reduce(lambda x,y:x+y,i,[])
N=5
string = flat([[i for j in range(10) ] for i in range(N)])
substr = flat([[i for j in range(5) ] for i in range(N)])
print("string:","".join(str(i) for i in string),"substr:","".join(str(i) for i in substr),sep="\n")
print("result:",subseqsearch(string,substr))

output (instantly):

string:
00000000001111111111222222222233333333334444444444
substr:
0000011111222223333344444
result: 1016255020032
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Now lets see you confirm the output – Dani Jul 31 '11 at 14:57
binomial(10,5)**5 -> goo.gl/s0BPW – Luka Rahne Jul 31 '11 at 18:23

My quick attempt:

def count_subseqs(string, subseq):
string = [c for c in string if c in subseq]
count = i = 0
for c in string:
if c == subseq[0]:
pos = 1
for c2 in string[i+1:]:
if c2 == subseq[pos]:
pos += 1
if pos == len(subseq):
count += 1
break
i += 1
return count

print count_subseqs(string='3141592653', subseq='123')

Edit: This one should be correct also if 1223 == 2 and more complicated cases:

def count_subseqs(string, subseq):
string = [c for c in string if c in subseq]
i = 0
seqs = []
for c in string:
if c == subseq[0]:
pos = 1
seq = [1]
for c2 in string[i + 1:]:
if pos > len(subseq):
break
if pos < len(subseq) and c2 == subseq[pos]:
try:
seq[pos] += 1
except IndexError:
seq.append(1)
pos += 1
elif pos > 1 and c2 == subseq[pos - 1]:
seq[pos - 1] += 1
if len(seq) == len(subseq):
seqs.append(seq)
i += 1
return sum(reduce(lambda x, y: x * y, seq) for seq in seqs)

assert count_subseqs(string='12', subseq='123') == 0
assert count_subseqs(string='1002', subseq='123') == 0
assert count_subseqs(string='0123', subseq='123') == 1
assert count_subseqs(string='0123', subseq='1230') == 0
assert count_subseqs(string='1223', subseq='123') == 2
assert count_subseqs(string='12223', subseq='123') == 3
assert count_subseqs(string='121323', subseq='123') == 3
assert count_subseqs(string='12233', subseq='123') == 4
assert count_subseqs(string='0123134', subseq='1234') == 2
assert count_subseqs(string='1221323', subseq='123') == 5
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Hm, it's probably more complicated than that. It would be good to see the original assignment. If, for example, this counts for two 1223 then my function is wrong. – jkbrzt Jul 29 '11 at 18:47
I guess 1223 counts for two :( – unkulunkulu Jul 31 '11 at 5:10
I've added another variant which should work correctly even if 1223 counts for two, 12233 for four, etc. – jkbrzt Jul 31 '11 at 11:23

psh. O(n) solutions are way better.

Think of it by building a tree:

iterate along the string if the character is '1', add a node to the the root of the tree. if the character is '2', add a child to each first level node. if the character is '3', add a child to each second level node.

return the number of third layer nodes.

this would be space inefficient so why don't we just store the number of nodes a each depth:

infile >> in;
long results[3] = {0};
for(int i = 0; i < in.length(); ++i) {
switch(in[i]) {
case '1':
results[0]++;
break;
case '2':
results[1]+=results[0];
break;
case '3':
results[2]+=results[1];
break;
default:;
}
}

cout << results[2] << endl;
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This will not work if the subsequence you are searching for has characters that are not distinct, for example '122'. – Dream Lane Aug 3 '12 at 17:51

# How to count all three-member sequences 1..2..3 in the array of digits.

## Quickly and simply

Notice, we need not FIND all sequences, we need only COUNT them. So, all algorithms that search for sequences, are excessively complex.

1. Throw off every digit, that is not 1,2,3. The result will be char array A
2. Make parallel int array B of 0's. Running A from the end, count for the each 2 in A the number of 3's in A after them. Put these numbers into the appropriate elements of B.
3. Make parallel int array C of 0's.Running A from the end count for the each 1 in A the sum of B after its position. The result put into the appropriate place in C.
4. Count the sum of C.

That is all. The complexity is O(N). Really, for the normal line of digits, it will take about twice the time of the shortening of the source line.

If the sequence will be longer, of , say, M members, the procedure could be repeated M times. And complexity will be O(MN), where N already will be the length of the shortened source string.

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You should make clear that this only works if the characters in the sequence to be searched for are all distinct. – j_random_hacker Apr 1 at 13:47
Your English is fine, but you misunderstood my question: "the sequence to be searched for" is 123 in this example, not 3141592653 (which could be called "the sequence to be searched in", or just "the sequence to be searched"). For example, suppose instead that we were looking for 1232 instead of 123. – j_random_hacker Apr 2 at 14:35
@j_random_hacker I see. I hope I'll look at it in a week. – Gangnus Apr 4 at 16:20