# Undirected Pair State

I'm looking for an "efficient" way to persist a binary state when given to two integers. Giving these two integers A an B, A is always less than B and the range of values which they will contain is 0 through N. The integer N will be greater than 2 and less than 256.

The simple solution is to create a two-dimensional array of Boolean values, but that leaves more than half of the array unused because there are unused values when B is less than or equal to A.

Does anyone know of a way to use less memory and still be "fast?"

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you could store both numbers in one integer (therefore one array index) by shifting b left by 8 bits and `or` ing them together –  Gabe Moothart Feb 17 '10 at 16:19
@Gabe: That doesn't work. (0,1)=0, (0,2)=0, (1,2)=1 –  Mike Feb 17 '10 at 16:56
What do you mean "persist a binary state"? Who writes this, and how often? Who reads it, and how often? Are you storing multiple pairs, or just one? What part of this process needs to be "fast"? –  Mike Dunlavey Feb 17 '10 at 18:15
@Mike Dunlavey: persisting a binary state meanings storing a Boolean (true/false). There will be orders of magnitude more reads than writes. Reads need to be "fast." I don't understand your question about pairs. –  Mike Feb 17 '10 at 18:23
OK, so you've got an (A,B) pair. You want to remember it between learning it and needing it. Is there just one such pair, or many (A1,B1), (A2, B2) ... (An,Bn). When you need it, are you asking "Does pair (x,y) exist?" where x and y are known, or are x and y not known (by the reader)? Could there be multiple such (x,y) pairs? –  Mike Dunlavey Feb 17 '10 at 18:29
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Here's some example C++ code that prints "pair" if the pair exists. This is just an example. In production code, N won't be known a compile-time and I would delete the allocated memory... etc.

``````#include <iostream>
using namespace std;
template<typename T>
void foo ( ) {
const int n = 3;
const unsigned int a = 8; // align to "a" bytes
// find the size of the first dimension
unsigned int s = (n-1) * sizeof(T**);
// find a size that aligns the second dimension
if (s%a) s=s/a*a+a;
T** p = (T**) malloc(s +
(n*n-n)/2 * sizeof(T));
T* j = (T*)p + s;
for (int i=0; i<n-1; i++) {
p[i] = j - (i+1);
j += (n - (i+1)) * sizeof(T);
}
// the "pair matrix" hasn't been populated
for (int i=0; i<n-1; i++)
for (int j=i+1; j<n; j++)
if (p[i][j])
cout << "pair" << endl;
}

int main(int argc, char* argv[])
{
foo<bool>();
return 0;
}
``````
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@Mike: you allocated an array of pointers to booleans. That isn't right, unless you do `bool** p = new bool*[n]` and then allocate each `p[i] = new bool[n-i+1]`. That spends a lot of memory on pointers, if you're worried about space, not to mention `bool` being 8 bits. –  Mike Dunlavey Feb 17 '10 at 19:43
Oops! It's fixed now. –  Mike Feb 17 '10 at 19:47
Sorry to keep buggin' you, but casting a `bool*` to a `bool**` is asking for trouble. It's really tricky to set up those pointers that point further down the same array of pointers. In fact, as I look at it, I really don't understand what you're doing. You've got a single array of bools, and you're using it as if it contains pointers. –  Mike Dunlavey Feb 17 '10 at 20:08
I've revised the code. I still need to look at the code a little closer in case there's some bugs. –  Mike Feb 17 '10 at 22:41

Wasting half of a matrix isn't such a terrible thing. If you add a new level of indirection, as you are willing to do, you need space for those pointers, and that space is comparable to that of integers in the first place. If you do any kind of bit packing, you will have to pay the time cost of the unpacking.

Anyway, the other solution I would prefer in C++ is storing the present pairs into a `set<pair<int, int>>`.

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If what you are trying to do is similar to indexing the element A[i][j] in an upper-triangular matrix, where N is the number of rows, you can calculate the index like this:

``````A[ N*j - j*(j-1)/2 + i ]
``````

for example if `N=4`, and `i=1`, `j=2`, then the index in the matrix is
`4*2 - 2*1/2 + 1 = 8-1+1 = 8`

``````    0  1  2  3
0: 0  4  7  9
1: 1  5  8
2: 2  6
3: 3
``````

Then it shouldn't be too hard to adapt the (I,J) to your (A,B). Then if you let A be a linear array of bits, that should be pretty compact.

On the other hand, if only one element of the array is ever set, you could just save the (A,B) pair and be done with it, because in the former case you need to remember N(N+1)/2 bits, while in the latter case you only need to remember 2*log(N) bits (base 2).

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I posted an answer that pre-computes a "secondary" index. –  Mike Feb 17 '10 at 19:34