# How to find minimal-length subsequence that contains all element of a sequence

Given a sequence such as S = {1,8,2,1,4,1,2,9,1,8,4}, I need to find the minimal-length subsequence that contains all element of S (no duplicates, order does not matter). How do find this subsequence in an efficient way?

Note: There are 5 distinct elements in S: {1,2,4,8,9}. The minimum-length subsequence must contain all these 5 elements.

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Any constraints on time/space complexity? – Anders Lindahl Aug 1 '11 at 9:36
O(n^2) is not enough. any O(nlgn) or O(n) algorithm?? – russell Aug 1 '11 at 9:38
number of element ,n be 10^5 and value of each element be <=10^5. – russell Aug 1 '11 at 9:41
Are the numbers only > 0 ? – Vash Aug 1 '11 at 9:50
You could use an adaptation of Boyer-Moore for this. Lookup would be a hashtable. Should be O(n) or less in the general case. – leppie Aug 1 '11 at 9:54

Algorithm:

First, determine the quantity of different elements in the array - this can be easily done in linear time. Let there be `k` different elements.

Allocate an array `cur` of size 10^5, each showing how much of each element is used in current subsequence (see later).

Hold a `cnt` variable showing how many different elements are there currently in the considered sequence. Now, take two indexes, `begin` and `end` and iterate them through the array the following way:

1. initialize `cnt` and `begin` as `0`, `end` as `-1` (to get `0` after first increment). Then while possible perform follows:
2. If `cnt != k`:

2.1. increment `end`. If `end` already is the end of array, then break. If `cur[array[end]]` is zero, increment `cnt`. Increment `cur[array[end]]`.

Else:

2.2 {

Try to increment the `begin` iterator: while `cur[array[begin]] > 1`, decrement it, and increment the `begin` (`cur[array[begin]] > 1` means that we have another such element in our current subsequence). After all, compare the `[begin, end]` interval with current answer and store it if it is better.

}

After the further process becomes impossible, you got the answer. The complexity is `O(n)` - just passing two interators through the array.

Implementation in C++:

``````    #include <iostream>

using namespace std;

const int MAXSIZE = 10000;

int arr[ MAXSIZE ];
int cur[ MAXSIZE ];

int main ()
{
int n; // the size of array
// read n and the array

cin >> n;
for( int i = 0; i < n; ++i )
cin >> arr[ i ];

int k = 0;
for( int i = 0; i < n; ++i )
{
if( cur[ arr[ i ] ] == 0 )
++k;
++cur[ arr[ i ] ];
}

// now k is the number of distinct elements

memset( cur, 0, sizeof( cur )); // we need this array anew
int begin = 0, end = -1; // to make it 0 after first increment
int best = -1; // best answer currently found
int ansbegin, ansend; // interval of the best answer currently found
int cnt = 0; // distinct elements in current subsequence

while(1)
{
if( cnt < k )
{
++end;
if( end == n )
break;
if( cur[ arr[ end ]] == 0 )
++cnt; // this elements wasn't present in current subsequence;
++cur[ arr[ end ]];
continue;
}
// if we're here it means that [begin, end] interval contains all distinct elements
// try to shrink it from behind
while( cur[ arr[ begin ]] > 1 ) // we have another such element later in the subsequence
{
--cur[ arr[ begin ]];
++begin;
}
// now, compare [begin, end] with the best answer found yet
if( best == -1 || end - begin < best )
{
best = end - begin;
ansbegin = begin;
ansend = end;
}
// now increment the begin iterator to make cur < k and begin increasing the end iterator again
--cur[ arr[ begin]];
++begin;
--cnt;
}

// output the [ansbegin, ansend] interval as it's the answer to the problem

cout << ansbegin << ' ' << ansend << endl;
for( int i = ansbegin; i <= ansend; ++i )
cout << arr[ i ] << ' ';
cout << endl;

return 0;
}
``````
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 Ok, Code seems right, i am examining. thanks for the effort you put so far. – russell Aug 1 '11 at 10:41 Didn't test the code myself, sorry if it contains any typos, but the solution should work :) – Grigor Gevorgyan Aug 1 '11 at 10:44 what is the breaking condition of while(1) loop?? – russell Aug 1 '11 at 10:57 Fixed the mistake, everything works now :) – Grigor Gevorgyan Aug 1 '11 at 10:58 the loop breaks when the program reaches the line if( end == n ) break; - i.e. the end iterator reached the end of the array and we currently have less then k distinct elements in our subsequence, so it's impossible to improve it – Grigor Gevorgyan Aug 1 '11 at 11:01

I've got a O(N*M) algorithm where N is the length of S, and M is the number of elements (it tend to works better for small values of M, i.e : if there are very few duplicates, it may be a bad algorithm with quadratic cost) Edit : It seems that in fact, it's much closer to O(N) in practise. You get `O(N*M)` only in worst case scenarios

Start by going through the sequence and record all the elements of S. Let's call this set E.

We're going to work with a dynamic subsequence of S. Create an empty `map` M where M associates to each element the number of times it is present in the subsequence.

For example, if `subSequence = {1,8,2,1,4}`, and `E = {1, 2, 4, 8, 9}`

• `M[9]==0`
• `M[2]==M[4]==M[8]==1`
• `M[1]==2`

You'll need two index, that will each point to an element of S. One of them will be called L because he's at the left of the subsequence formed by those two indexes. The other one will be called R as it's the index of the right part of the subsequence.

Begin by initializing `L=0`,`R=0` and `M[S[0]]++`

The algorithm is :

``````While(M does not contain all the elements of E)
{
if(R is the end of S)
break
R++
M[S[R]]++
}
While(M contains all the elements of E)
{
if(the subsequence S[L->R] is the shortest one seen so far)
Record it
M[S[L]]--
L++
}
``````

To check if M contains all the elements of E, you can have a vector of booleans V. `V[i]==true` if `M[E[i]]>0` and `V[i]==false` if `M[E[i]]==0`. So you begin by setting all the values of V at `false`, and each time you do `M[S[R]]++`, you can set V of this element to `true`, and each time you do `M[S[L]]--` and `M[S[L]]==0` then set V of this element to `false`

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How do you control the sequence in a map or set? – leppie Aug 1 '11 at 9:58
I control the subsequence with the two indexes. The map is here to indicate what are the elements inside the subsequence. – Fezvez Aug 1 '11 at 10:08
I thought this type of idea. But i am afraid this will not work for large number of distinct number Like 50000 distinct number So complexity goes to O(50000*50000). However ,many many thanks for your reply. – russell Aug 1 '11 at 10:23
I edited my answer, so as to tell that in fact, it's O(N) and is more or less independent of M. You should accept Grigor's solution, it's identical to mine, except that it includes a cute trick with `cnt` that makes it totally O(N) – Fezvez Aug 1 '11 at 10:44

This can be solved by dynamic programming.

At each step `k`, we'll compute the shortest subsequence that ends at the `k`-th position of `S` and that satisfies the requirement of containing all the unique elements of `S`.

Given the solution to step `k` (hereinafter "the sequence"), computing the solution to step `k+1` is easy: append the `(k+1)`-th element of S to the sequence and then remove, one by one, all elements at the start of the sequence that are contained in the extended sequence more than once.

The solution to the overall problem is the shortest sequence found in any of the steps.

The initialization of the algorithm consists of two stages:

1. Scan `S` once, building the alphabet of unique values.
2. Find the shortest valid sequence whose first element is the first element of `S`; the last position of this sequence will be the initial value of `k`.

All of the above can be done in `O(n logn)` worst-case time (let me know if this requires clarification).

Here is a complete implementation of the above algorithm in Python:

``````import collections

S = [1,8,2,1,4,1,2,9,1,8,4,2,4]

# initialization: stage 1
alphabet = set(S)                         # the unique values ("symbols") in S
count = collections.defaultdict(int)      # how many times each symbol appears in the sequence

# initialization: stage 2
start = 0
for end in xrange(len(S)):
count[S[end]] += 1
if len(count) == len(alphabet):         # seen all the symbols yet?
break
end += 1

best_start = start
best_end = end

# the induction
while end < len(S):
count[S[end]] += 1
while count[S[start]] > 1:
count[S[start]] -= 1
start += 1
end += 1
if end - start < best_end - best_start: # new shortest sequence?
best_start = start
best_end = end

print S[best_start:best_end]
``````

Notes:

1. the data structures I use (dictionaries and sets) are based on hash tables; they have good average-case performance but can degrade to `O(n)` in the worst case. If it's the worst case that you care about, replacing them with tree-based structures will give the overall `O(n logn)` I've promised above;
2. as pointed out by @biziclop, the first scan of `S` can be eliminated, making the algorithm suitable for streaming data;
3. if the elements of `S` are small non-negative integers, as your comments indicate, then `count` can be flattened out into an integer array, bringing the overall complexity down to `O(n)`.
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 I think you can probably get away with not scanning the entire sequence for the alphabet, if you keep track during each step of how many different characters you have in your subsequence and then choose the one with the maximum different characters. But the advantage of this approach is only worth it if you're working with streaming data. – biziclop Aug 1 '11 at 11:26

If you need to do this quite often for the same sequence and different sets you can use inverted lists for this. You prepare the inverted lists for the sequence and then collect all the offsets. Then scan the results from the inverted lists for a sequence of m sequential numbers.

With `n` the length of the sequence and `m` the size of the query the preparation would be in `O(n)`. The response time for the query would be in `O(m^2)` if I am not miscalculating the merge step.

If you need more details have a look at the paper by Clausen/Kurth from 2004 on algebraic databases ("Content-Based Information Retrieval by Group Theoretical Methods"). This sketches out a general database framework that can be adapted to your task.

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 I think I misunderstood the question so using inverted lists probably does not work in this case. – LiKao Aug 1 '11 at 13:03

Here is an algorithm that requires O(N) time and O(N) space. It is similar to that one by Grigor Gevorgyan. It also uses an auxiliary O(N) array of flags. The algorithm finds the longest subsequence of unique elements. If `bestLength < numUnique` then there is no subsequence containing all unique elements. The algorithm assumes that the elements are positive numbers and that the maximal element is less than the length of the sequence.

``````bool findLongestSequence() {
const int N = 13;
char flags[N];
int a[] = {1,8,2,1,4,1,2,9,1,8,1,4,1};

// Number of unique elements
int numUnique = 0;
for (int n = 0; n < N; ++n) flags[n] = 0; // clear flags
for (int n = 0; n < N; ++n) {
if (a[n] < 0 || a[n] >= N) return false; // assumptions violated
if (flags[a[n]] == 0) {
++numUnique;
flags[a[n]] = 1;
}
}

// Find the longest sequence ("best")
for (int n = 0; n < N; ++n) flags[n] = 0; // clear flags
int bestBegin = 0, bestLength = 0;
int begin = 0, end = 0, currLength = 0;
for (; begin < N; ++begin) {
while (end < N) {
if (flags[a[end]] == 0) {
++currLength;
flags[a[end]] = 1;
++end;
}
else {
break; // end-loop
}
}
if (currLength > bestLength) {
bestLength = currLength;
bestBegin = begin;
}
if (bestLength >= numUnique) {
break; // begin-loop
}
flags[a[begin]] = 0; // reset
--currLength;
}

cout << "numUnique = " << numUnique << endl;
cout << "bestBegin = " << bestBegin << endl;
cout << "bestLength = " << bestLength << endl;
return true; // longest subseqence found
}
``````
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I'd say:

1. Construct the set of elements D.
2. Keep an array with the same size as your sequence S.
3. Fill the array with indexes from S indicating the latest start of a sequence with all elements from D that ends at that index.
4. Find the min length of sequences in the array and save the position for start and end.

Obviously, only item 3. is tricky. I'd use a priority queue / heap that assigns a key to each element from D and has the element as value. Apart from that you'll want a data structure that is able to access the elements in the heap by their value (map w/ pointers to the elements). The key should always be the last position in S that the element has occurred.

So you go through S and for each char you read, you do one of setKey O(log n) and then look at the current min O(1) and write it to in the array.

Should be O(n * log n). I hope I didn't miss anything. It just came to my mind, so take it with a grain of salt, or let the community point out possible mistakes I might have made.

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