# How to combine 2 partially sorted arrays?

Given 2 arrays with int, A1 and A2. A1 length is L1, A2 length is L1+L2. The first L2 elements of A1 and A2 have been sorted. Combine the first L2 elements into A2. e.g.

A1:  1  3  6  0
A2:  2  5  7  13  10 22 11
result:
A1 + A2:  1 2 3 5 6 7 13 10 22  11

my solutions:

Pick each element by putting min { A1[i], A2[i]} into a array B[i], O(2 * L2) Copy B to A2. O(L1 + L2).

Unsorted part should not be changed.

Any better solutions ?

thanks

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Well, I've tried a few ideas, but none of them take into account the nearly sorted-ness of your values. My gut tells me you should be able to get slightly better, but not much. Even bucket sort throws away most of the advantage of your pre-sort. Still thinking about it though... – Michael Dorgan Dec 9 '11 at 22:20
By "Combine the first L2 elements into A2", do you mean "the first L1+L2 elements"? It would seem so, since you define the A2.length as L1+L2, and L2 would be an important number to keep, since you want to keep the last L2 numbers and append them. – matthias Dec 9 '11 at 22:29
A2 size will be L2 +L2 + L1 (sorted + unsorted) – user1002288 Dec 9 '11 at 22:36
What's with the trailing 0 at the end of A1? – Mooing Duck Dec 9 '11 at 22:45

int* semiMerge(int*, int, int*, int);

int main() {
const int A1[] = {1, 3, 6, 0};
const int A2[] = {2, 5, 7, 13, 10, 22, 11};

const int L1 = sizeof(A1)/sizeof(int);
const int L2 = sizeof(A2)/sizeof(int) - L1;

int* out = semiMerge(A1, L1, A2, L2);
}

int* semiMerge(A1, L1, A2, L2) {
int* output = new int[L2 + L2 + L1];

//merge does a sorted combination of the items--both sets must be sorted up to the endpoints;
//we want to merge only the first L1 results from each array
std::merge(A1, A1 + L2,
A2, A2 + L2,
output);
//at this point, we have an array of 2*L1 elements, all sorted properly.

//we want to start looking at the first element we didn't copy from A2,
//the -1 is to account for the fact that begin() + L1 is the start of the L1+1th slot
std::copy(A2 + L2,
A2 + L2 + L1,
(output + L2 + L2 - 1));

return output;
}

I chose to show A1 and A1 as static arrays, but if you're getting them as int*s to heap-allocated arrays, and if it's important that the finished array be placed in L2, you can then say delete[] L2; L2 = out; after the call to semiMerge(). I chose not to do this in main because I represented A2 as a static array, while switching it out for the contents of out would require it to be a pointer to a dynamic array.

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Completed your method and made sure no memory is leaked. – André Caron Dec 10 '11 at 0:22
@AndréCaron uh, maybe I'm missing something, but the only change I see is that you changed output to a std::vector<int>, which, because you didn't change the type of the variable it's stored in, just breaks the code... It was valid to act directly on a dynamic int array, as long as the client remembers to call delete[]. – matthias Dec 10 '11 at 1:28
@mathias: It's the other way around. I changed the type of the output variable, not the return type of the function. Your previous example was invalid since (1) it attempted to construct a vector from a single int* argument and (2) it always leaked the allocated memory since the only pointer to it was in a local variable. – André Caron Dec 10 '11 at 1:31
@mathias: I didn't notice that the function forward declaration and main() were expecting int* as output though. Nice catch! – André Caron Dec 10 '11 at 1:33
Yeah, I had originally implemented it in terms of vector, but decided to lower it to int* because the OP is talking about dealing with arrays. You caught the one part I missed and did the inverse of what I should have done. Also, you do return the pointer to the array, and it's the client's responsibility to manage it at that point. I did use the wrong delete in the bottom paragraph though; I've changed that. – matthias Dec 10 '11 at 1:35

Now that I've figured out what L1 and L2 are:

{
std::vector<int> B(L2+L2+L1, 0);
std::merge(A1.begin(), A1.begin()+L2, A2.begin(), A2.begin()+L2, B.begin());
if (L1 > L2)
B.insert(B.end(), A2.begin()+L2, A2.end());
A2.swap(B);
}

B contains [merged sorted part][unsorted A2]. Is that the correct format? This is the algorithm you posted. In place (like Nim) is slower, but uses less memory, so it's a trade-off.

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1. Copy A1 and A2 into one array
2. std::inplace_merge with begin, begin + L2, end

(well you didn't specify no library functions!) ;)

This sounds like a homework problem, and I normally hesitate before providing code for homework. However it looks like an example is required here:

std::vector<int> A1; // initialize to { 1  3  6  0 }
std::vector<int> A2; // initialize to { 2  5  7  13  10 22 11 }

// Now assumption here is that we want L2 items from A1, so let's copy
A2.insert(A2.begin(), A1.begin(), A1.begin() + L2);

// Now A2 contains the sorted range from A1 0 is dropped (?)
// Now call inplace_merge, this leaves the unsorted segment of A2 alone, and only includes
// L2 items from A2.
std::inplace_merge(A2.begin(), A2.begin() + L2, A2.begin() + (2*L2));
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it is (2 * L2 * lg 2*L2). when L2 >> L1, it is not efficient. – user1002288 Dec 9 '11 at 22:16
what's wrong with merge(begin(A1), end(A1), begin(A2), end(A2), back_inserter(dest));? – Mooing Duck Dec 9 '11 at 22:18
@mooing, yes if B can be a separate array, if A2 (or A1) is enough for both the inplace is better I guess... – Nim Dec 9 '11 at 22:22
In that case inplace is deffinitely better, end would be the end of the two sorted ranges. That would leave the unsorted segment alone. I would double check the NlogN claim... – Nim Dec 9 '11 at 22:26
Part of A2 is sorted and another part is not, and they should remain in this state. Why these parts aren't kept in different arrays? This would simplify everything and provide O(2* L2). – Andy T Dec 9 '11 at 22:35