# Algorithm to match sequential subset from a list

I am trying to remember the right algorithm to find a subset within a set that matches an element of a list of possible subsets. For example, given the input:

``````aehfaqptpzzy
``````

and the subset list:

``````{ happy, sad, indifferent }
``````

we can see that the word "happy" is a match because it is inside the input:

`a e h f a q p t p z z y`

I am pretty sure there is a specific algorithm to find all such matches, but I cannot remember what it is called.

UPDATE

The above example is not very good because it has letter repetitions, in fact in my problem both the dictionary entries and the input string are sortable sets. For example,

input: acegimnrqvy

dictionary: { cgn, dfr, lmr, mnqv, eg }

So in this example the algorithm would return cgn, mnqv and eg as matches. Also, I would like to find the best set of complementary matches where "best" means longest. So, in the example above the "best" answer would be "cgn mnqv", eg would not be a match because it conflicts with cgn which is a longer match.

I realize that the problem can be done by brute force scan, but that is undesirable because there could be thousands of entries in the dictionary and thousands of values in the input string. If we are trying to find the best set of matches, computability will become an issue.

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It sounds like you really have a list, not a set. A set doesn't have an order, nor does it contain duplicates... – Oliver Charlesworth Jan 5 '14 at 10:28
Do the matches have to be in order in the target string? – David-SkyMesh Jan 5 '14 at 10:28
At which point, surely the algorithm is just a simple left-to-right scan? Which would be `O(MN)` (where `M` is the number of target words, `N` is the number of letters in the original list). – Oliver Charlesworth Jan 5 '14 at 10:31
Define "all such matches". For input `ssaadd`, should it find 6 matches for `sad`? Or do you just want to check whether `sad` exists at all? – Dukeling Jan 5 '14 at 18:11
Its a set. I have simplified the problem. The actual problem involves acoustic frequency sets. So for example, an acoustic signature might be 100/51 150/30 175/35 190/17 where the first number is the frequency and the second is the amplitude. The problem is to find if the acoustic signature is present in a set of tonals from an environment. – Tyler Durden Jan 5 '14 at 23:08

About the complexity - this could be as slow as the naive `O(MN)` approach, because there can be up to `size of dictionary` actors. However, in practice, we can make a good use of the fact that many words are substrings of others, because there never won't be more than `size of the trie` actors, which - compared to the size of the dictionary - tends to be much smaller.