# Hoare partitioning algorithm - strict or not strict inequalities?

I'm having a really hard time with the implementation of Hoare's partition algorithm. Basically, what i want to do is split an array into two parts, the first one containing numbers lesser than the given `x`, and the other one containing the greater. However, I just can't figure out a good implementation. This is my code:

``````void hoare(vector<int>&arr,int end, int pivot)
{
int i = 0;
int j = end;

while (i < j)
{
while (arr[i] < pivot)
i += 1;

while (arr[j] > pivot)
j -= 1;

swap(arr[i],arr[j]);
}

// return arr;
for (int i=0; i<end; i++)
printf("%d ", arr[i]);
}
``````

Now I've found out that loads of sites have while `(arr[i] <= pivot)` instead of what I put down there. However, when I do that, for an array like this:

``````1 3 5 7 9 2 4 6 8
``````

I get:

``````1 3 5 4 9 2 7 6 8
``````

But then again, in my version, for such a set:

``````12 78 4 55 4 3 12 1 0
``````

the program freezes, because since neither condition in the outer loop is fulfilled, it just goes through it over and over again, without incrementing `j` or `i`.

The pivot is a pointer to a specific number in the array, counting from 1; for instance, number 3 passed to function in the first example would mean the `pivot` equals `arr[2]`, which is 5

Sorry if that's a noob question or has already been answered, but I've spent the whole day on this (also searching the net for a solution) to no avail and now I'm having suicidal thoughts.

-
The pivot is a pointer to a specific number in the array, counting from 1; for instance, number 3 passed to function in the first example would mean the pivot equals arr[2], which is 5. –  szczurcio Dec 25 '12 at 18:56
could you update your question to add that information? and also add which values you actually used? –  didierc Dec 25 '12 at 19:01
You seem confused about what `pivot` is. If it's an index in the array then it doesn't make sense to compare it with an element of the array like your code does in `arr[i] < pivot`. Imagine the array being an array of strings, you would be comparing a string with an integer. –  6502 Dec 25 '12 at 19:01
–  J.F. Sebastian Dec 25 '12 at 19:03
have a look at this SO question. –  didierc Dec 25 '12 at 19:05
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The simple answer to partion a sequence is, of course, to use

``````auto it = std::partition(vec.begin(), vec.end(),
std::bind2nd(std::less<int>(), pivot));
``````

The function doesn't really care about the predicate but rearranges the sequence into two sequences: one for which the predicate yields `true` and one for which the predicate yields `false`. The algorithm returns an iterator to the end of the first subsequence (consisting of the elements for which the predicate is `true`). Interestingly the algorithm is supposed to work on forward iterators (if it really gets forward iterators it can use quite a number of swaps, though). The algorithm you are implementing clearly requires bidirectional iterators, i.e., I'll ignore the requirement to also work for forward sequences.

I'd follow exactly the same interface when implementing the algorithms because the iterator abstraction works very well for sequence algorithms. The algorithm itself simply employs `std::find_if()` to find an iterator `it` in the range `[begin, end)` such that the predicate does not hold:

``````it = std::find_if(begin, end, not1(pred));
``````

If such an iterator exists it employs `std::find_if()` to search in `[std::reverse_iterator<It>(end), std::reverse_iterator<It>(it))` for an iterator `rit` such that the predicate does hold:

``````rit = std::find_if(std::reverse_iterator<It>(end), std::reverse_iterator<It>(it),
pred);
``````

If such an iterator exists, it `std::swap()`s the corresponding locations and updates `begin` and `end` accordingly:

``````std::swap(*it, *rit);
begin = ++it;
end = (++rit).base();
``````

If either `it` or `rit` isn't found, the algorithm terminates. Putting this logic into a consistent algorithm seems to be rather straight forward. Note that this algorithm can't even use the operator you try to use, i.e., conceptually elements can only be compared for `x < pivot` and `x >= pivot` (which is identical to `!(x < privot)`).

The implementation below isn't tested but the complete algorithm would look something like this:

``````template <typename BiIt, typename Pred>
BiIt partition(BiIt it, BiIt end, Pred pred) {
typedef std::reverse_iterator<BiIt> RIt;
for (RIt rit(end);
(it = std::find_if(it, end, std::not1(pred))) != end
&& (rit = std::find_if(RIt(end), RIt(it), pred)) != RIt(it);
++it, end = (++rit).base()) {
std::swap(*it, *rit);
}
return it;
}
``````
-
Ok, I'll express myself more clearly. Basically, I have an array of positive integers, then, given the position of a number (let's call it x) in that set, I should arrange them in such an order that all numbers lesser than x precede it, whereas any number greater than x should be put farther in the array. If, by chance, there exists another number, equal to x, it should be put next to it. For instance, for the following input: 3 1 3 5 7 9 2 4 6 8 the answer should look like this: 3 1 4 2 5 9 6 8 7 Where number 3 in the first line of the input means the position o –  szczurcio Dec 25 '12 at 19:49
@user1928235: I understand how partition works although your requirement that equal numbers are specifically arranged is normally not required and actually not supported by the nature of the algorithm. It can be achieved using two partitions, though: Once the predicate is `val < x` and then the predicate is `val == x`. Except for silly mistakes I'm pretty sure that the algorithm above implements the correct logic (it isn't tested, though, and I generally have little faith in untested code). –  Dietmar Kühl Dec 25 '12 at 19:55
Ok, I'm pretty confused now. I understand what You're saying (well, apart from some of the code, I guess), but then, what is this: stackoverflow.com/questions/7198121/… about? Their implementation is very similar to mine. –  szczurcio Dec 25 '12 at 20:02
@rici: Yes, there is 3-way partition but Hoare Partition isn't a 3-way partition. I didn't find a direct references for Hoare Partition and, thus, assume that the algorithms in "Introduction to Algorithms", 3rd Edition, Corman et al., page 185, is "Hoare Partition". The above algorithm is different in a subtle way (you'd need to negate the predicate to get Hoare Partition) but neither of these two algorithms sorts elements equal to the pivot together. –  Dietmar Kühl Dec 25 '12 at 20:19
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