Subsequence of a string

I have to write a program that takes string argument s and integer argument k and prints out all subsequences of s of length k. For example if I have

``````subSequence("abcd", 3);
``````

the output should be

`````` abc abd acd bcd
``````

I would like guidance. No code, please!

Update:

I was thinking to use this pseudocode:

``````Start with an empty string
Append the first letter to the string
Append the second letter
Append the third letter
Print the so-far build substring - base case
Return the second letter
Append the fourth letter
Print the substring - base case
Return the first letter
Append the third letter
Append the fourth letter
Print the substring - base case
Return third letter
Append the second letter
Append the third letter
Append the fourth letter
Print the substring - base case
Return the third letter
Return the second letter
Append the third letter
Append the fourth letter
Return third letter
Return fourth letter
Return third letter
Return second letter
Return first letter
``````

The different indent means going deeper in the recursive calls.

(In response to Diego Sevilla):

``````private String SSet = "";
private String subSequence(String s, int substr_length){
if(k == 0){
return SSet;
}
else{
for(int i = 0; i < substr_length; i++){
subString += s.charAt(i);
subSequence(s.substring(i+1), k-1);
}
}
return SSet;
}
}
``````
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unique subsequences? E.g give example for abacd –  Max Jul 13 '11 at 23:09
Would `dcb` be a valid sequence or does it have to correspond to the given order of the string argument? –  SonOfStalin Jul 13 '11 at 23:12
@Max: aba, abc, abd, bac, bad and so on. I guess the description of the problem is not very explanatory but this is what I have. –  Nath Jul 13 '11 at 23:23
Are you sure you are talking about sub sequences and not sub sets? A subsequence should only contain consecutive letters. –  Gary Buyn Jul 14 '11 at 0:21

As you include "recursion" as a tag, I'll try to explain you the strategy for the solution. The recursive function should be a function like that you show:

``````subSequence(string, substr_length)
``````

that actually returns a `Set` of (sub)-strings. Note how the problem could be divided in sub-problems that are apt to recursion. Each subSequence(string, substr_length) should:

2. Do a loop from 0 to the length of the string minus substr_length
3. In each loop position i, you take string[i] as the beginning character, and call recursively to `subSequence(string[i+1..length], substr_length - 1)` (here the `..` imply an index range into the string, so you have to create the substring using these indices). That recursive call to `subSequence` will return all the strings of size `substr_length -1`. You have to prepend to all those substrings the character you selected (in this case string[i]), and add all of them to the SSet set.
4. Just return the constructed SSet. This one will contain all the substrings.

Of course, this process is highly optimizable (for example using dynamic programming storing all the substrings of length i), but you get the idea.

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I tried to make some kind of pseudocode - please, see the update of my post. –  Nath Jul 13 '11 at 23:28
@Nath, this could show how it will be executing things, but it is not a pseudo-code (for example, you don't show recursive calls). –  Diego Sevilla Jul 13 '11 at 23:52
Yes, you are right. Since I was not able to make the pseudocode I decided to start from the end and going back to try to write the pseudocode based on this sequence of steps. –  Nath Jul 14 '11 at 0:02
I apologize for the late response. I've updated my original post in order to try your suggestion but I am still missing details. Can you, please look at the update? –  Nath Jul 14 '11 at 21:55
Actually I don't think your suggestion is going to work. –  Nath Jul 15 '11 at 22:32

So, I see you want to implement a method: `subSequence(s, n)`: Which returns a collection of all character character combinations from `s` of length `n`, such that ordering is preserved.

In the spirit of your desire to not provide you with code, I assume you would prefer no pseudo-code either. So, I will explain my suggested approach in a narrative fashion, leaving the translation to procedural code as an exercise-to-the-reader(TM).

Think of this problem where you are obtaining all combinations of character positions, which could be represented as an array of bits (a.k.a. flags). So where `s="abcd"` and `n=3` (as in your example), all combinations could be represented as follows:

``````1110 = abc
1101 = abd
1011 = acd
0111 = bcd
``````

Note, that we start with a bit-field where all characters are turned "on" and then shift the "off" bit over by 1. Things get interesting in an example where `n < length(s) - 1`. For example, say `s="abcd"` and `n=2`. Then we have:

``````1100 = ab
1010 = ac
0110 = bc
0101 = bd
0011 = cd
``````

The recursion comes into play when you analyze a sub set of the bit-fields. Hence, a recursive call would reduce the size of the bit-field and "bottom-out" where you have three flags:

``````100
010
001
``````

The bulk of the work is a recursive approach to find all of the bit-fields. Once you have them, the positions of each bit can be used as an index in the the array of characters (that is `s`).

This should be sufficient to get you started on some pseudo-code!

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after some of his comments, I realized he did care about the order of the substrings... so this solution is not what he wants... I edited my answer 'cause of that –  woliveirajr Jul 14 '11 at 2:31

The problem is precisely this:

Given an ordered set S : {C0, C1, C2, ..., Cn}, derive all ordered subsets S', where each member of S' is a member of S, and relative order of {S':Cj, S':Cj+1} is equivalent to relative order {S:Ci, S:Ci+d} where S':Cj = S:Ci and S':Cj+1 = S:Ci+d. |S|>=|S'|.

• Assume/assert size of set S, |S| is >= the size of the subset, |S'|
• If |S| - |S'| = d, then you know each of the subsets S' begins with digit at Si, where 0 < i < d.

e.g given S:{a, b, d, c} and |S'| = 3

• d = 1
• S' sets begin with 'a' (S:0), and 'b' (S:1).

So we see the problem is actually to solve d lexically ordered permutations of length 3 of subsets of S.

• @d=0: get l.o.permutations of length 3 for {a, b, c, d}
• @d=1: get l.o.permutations of length 3 for {b, c, d}
• @d=2: d > |S|-|S'|. STOP.
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