# looking for efficient algorithm (non-trivial) [closed]

The problem "specification":

It's Christmas! You have to buy presents!

You have a set of already existing bundles of toys, and the corresponding price of the bundle:

``````1 0 0 1 0 1 1 1 0 => 58
0 1 0 0 1 1 1 0 0 => 27
1 1 1 0 0 0 1 0 0 => 46
0 0 0 0 1 1 1 1 0 => 73
...
``````

Where a `1` indicates that the toy is in the bundle, and a `0` that it is not.

Now, Santa Claus promo is coming and a leftover bundle `X` is offered to you at a "special promo price". We will say `X` is a bad deal if there exists another bundle `Y` so that:

Edit: to make it easier, I dropped condition 3 but changed condition 1 from "subset" into "strict subset"

1. `X` is a strict subset of `Y`
2. `X` is more expensive than `Y`

The objective is to implement a function `bool isBadSubset(X)` which finds out efficiently whether `X` is good or not.

Given that there are millions of bundles, comparing it to each one is obviously not feasible. Moreover, you can take the assumption that in the existing collection of bundles, a subset of toys is always cheaper than a superset.

Tips:

• comparing whether a set is a subset or not of another set is easy
• one may limit the comparisons to set which are both containing at least `N` more toys and cheaper. However, the list might still be big.
• something in the direction of a sieve would be good
• you don't need to know which bundle is better ...just that there exists one which is better

The challenge: is it possible to achieve this in constant time? (independent of the amount of bundles presently in the collection) ...or at least in log(n)?

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for the "close" voters. Please state why. –  arnaud Sep 11 '11 at 9:59
No, it isn't possible to achieve this in constant time, since even examining the input X will take more than that. –  interjay Sep 11 '11 at 10:05
@arnaud: (1) should not the function be called `bool isGoodDeal(X)`? (2) what do you mean by constant time - independent of what? –  Jiri Sep 11 '11 at 10:07
@interjay: by constant time I mean independent of the amount of vectors obviously, not length of the vector –  arnaud Sep 11 '11 at 10:09
@arnaud: But the number of vectors is dependent on the length of the vector (it can be no more than 2^L) –  interjay Sep 11 '11 at 10:10
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## closed as too localized by Mat, Juhana, Ian Mercer, Richard, GravitonSep 13 '11 at 1:59

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I managed to find some relevant literature on a quick search, and it seems that in the general case your problem is not easy.

Charikar, Indyk and Panigrahy (2002) study the subset query problem: given a set P of N subsets of some universe U of m elements, and a query set Q, is there a set in P that is a superset of Q ? They present two algorithms which trade of storage space for query speed. In order to achieve O(N/k) query time they need to increase space usage by a factor exponential in the square root of k.

Bevc and Sannik (2010) describe a simple trie-based data structure for subset queries with no analysis of query speed, but it seems clear that it is worst-case linear in the number N of stored sets.

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Asking for a solution in O(1) is unrealistic, I think. The only solution I could think of would be generating a full list of bundles and for each indicating whether it is a good one or not... I doubt this is what you are asking for.

A simple binary search might prove interesting though, not even going down into the details of which toys are concerned, we can simply index on the price and the number of items. Our item is a bad bundle if there exists another with a lower price and a higher number of items.

We can therefore define a key `(price, nb items)` and order them efficiently. The search will be `O(n log n)`, and then the inclusion tests on the subset will still be linear.

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Ok, so the amount of toys, n, is constant and small, i.e. you have the set {toy_0, .. toy_n-1}.

Then you can have an array `Set[n] bundleContainingToy`, and if bundle x contain toy_i, then you save x in set bundleContainingToy[i].

If you get a new bundle 1 0 0 1 0 1 you have only have to compute the intersection bundleContainingToy[0], bundleContainingToy[3] and bundleContainingToy[5]. If intersection is O(1) (which you can probably assume, since you said that checking the subset property is) then you can do this check in O(1) too, since n is a constant (and small).

Is this the sieve you were looking for? The rest of your computation is only dependent on the number of bundles that contain toy_0, toy_3 and toy_5.

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Computing intersection is obviously not O(1) since any set `bundleContainingToy[i]` will contain gazillions of bundles, up to 2^(n-1)! –  arnaud Sep 11 '11 at 10:30
No, bundleContainingToy[i] will only contain the good bundles, not any bundle. –  DaveFar Sep 11 '11 at 10:32
`(1 1 0 0 0 0), (1 0 1 0 0 0), (1 1 1 0 0 0) and (1 ...)` are `2^(n-1)` equally good bundles that could be in `bundleContainingToy[0]` ...or did I miss something? –  arnaud Sep 11 '11 at 10:36
Hm, okay, it depends on your situation how many good bundles you can have. In a bad case, still a lot... –  DaveFar Sep 11 '11 at 10:38
@DaveBall, NP-completeness is judged based on the length of the input. In this case, the linear solution is actually linear in the size of the input, so it's certainly not NP-complete. –  svick Sep 11 '11 at 15:04
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If the requirement is that the lookup part should be `O(1)`, you could first construct a map:

``````map = {}
for (bundle, price) in bundles:
for subset in subsets(bundle): #including bundle
if map.contains(bundle)
map[bundle] = min(map[bundle],price)
else
map[bundle] = price
``````

Now to check if it's a bad deal:

``````  def isBadDeal(bundle,price)
return map[bundle] < price
``````
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...please read the original question again. Your suggestion does not satisfy the criteria of a bad deal. If it were just a map lookup, I wouldn't have made a post out of it ;) –  arnaud Sep 11 '11 at 14:22
You can turn any problem into a map lookup. y=f(x) => y=f[x]. The lookup is O(1), but creating the array is O(n). Your question said didn't specify which part of the algorithm that was time critical. Since you need to read in the bundles, it is already O(n), but if we already have them, we can already also have populated the map, and can thus do isBadDeal in O(1) –  nulvinge Sep 11 '11 at 14:53
the point is not to lookup a bundle!!! The point is to know if there exists a superset (with at least `N` more elements) which is cheaper! Of course you could then do `2^k` lookups, but this is even more pointless than traversing the list of bundles directly. –  arnaud Sep 11 '11 at 15:04
My solutions does exactly that. map[bundle] gives you the price of a superset of a bundle. Look at how map is constructed. I simply transform your problem from `any superset(bundle) in bundles` to `bundle in subsets(bundles)`. If map contains bundle, then there exists a superset of bundle in bundles, because I have added all subsets of all bundles to map. –  nulvinge Sep 11 '11 at 15:13
How often do the set of existing bundles change compared to the frequency of lookups? An 2^k setup time might be ok if it is only done once. –  AShelly Sep 12 '11 at 1:02
show 4 more comments

A bitwise and between the bundle and all bundles should identify which bundles contain the bundle subset. This followed by an inequality test will return whether or not there exists a more expensive set containing this subset. If any more expensive are found, then the bundle is a bad deal.

In Python / numpy:

``````import numpy

return ((bundles & bundle == bundle) * (prices < cost)).any()

# Generate some test data
numpy.random.seed(11)
global bundles, prices
bundles = numpy.random.randint(0,511,(1000000,)) # 000000000 to 111111111
prices = numpy.random.randint(40,70, (1000000,)) # 40 to 70\$
``````

A better solution is to keep only bundles less expensive than the cost first, then check if the bundle is present in that subset, which means we have a bad deal:

``````def bad_deal_2(bundle, cost):
less_exp_bundles = numpy.delete(bundles, numpy.where(prices > cost))
return (less_exp_bundles & bundle == bundle).any()
``````

In this case, the worst scenario is that the bundle is the most expensive item and that all other bundles are supersets of it, which requires checking all bundles. In all other cases we are checking less than the total number of bundles. It is however necessary to check all the prices (but there is less data in this vector than in the bundles vector) so checking prices first makes more sense in order to reduce the number of bundles we need to examine.

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This is still linear in the amount of bundles, so it's not any better than the straightforward solution. –  svick Sep 11 '11 at 18:54
What is the straightforward solution? –  Benjamin Sep 11 '11 at 23:33
Comparing to each vector in turn. You may gain some speed compared, but you won't gain on complexity. –  Matthieu M. Sep 12 '11 at 13:10