Given XOR & SUM of two numbers. How to find the numbers?

Given XOR & SUM of two numbers. How to find the numbers? For example, x = a+b, y = a^b; if x,y are given, how to get a, b? And if can't, give the reason.

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If you had actually cut-and-pasted the assignment, the grammar would be better. –  Beta Sep 11 '13 at 3:51
You can't. Counterexample: x=9, y=5: 3+6==9, 3^6==5. 2+7==9, 2^7==5. –  Blorgbeard Sep 11 '13 at 3:51
Also, why is this tagged `bitwise-and`? –  Blorgbeard Sep 11 '13 at 3:53

2 Answers

Can't be done. One counter example is 0/100 and 4/96. Both these sum to 100 and xor to 100.

Hence given a sum of 100 and an xor result of 100, you cannot know which of the possibilities generated those two numbers.

For what it's worth, this program checks the possibilities with just the number `0..255`:

``````#include <stdio.h>
static void output (unsigned int a, unsigned int b) {
printf ("%u:%u=%u %u\n", a+b, a^b, a, b);
}
int main (void) {
unsigned int limit = 256;
unsigned int a, b;
output (0, 0);
for (b = 1; b != limit; b++)
output (0, b);
for (a = 1; a != limit; a++)
for (b = 1; b != limit; b++)
output (a, b);
return 0;
}
``````

You can then take that output and massage it to give you all the repeated possibilities:

``````testprog | sed 's/=.*\$//' | sort | uniq -c | grep -v ' 1 '
``````

which gives:

``````  7 100:100
2 100:16
4 100:18
2 100:2
4 100:20
4 100:24
8 100:26
2 100:4
2 100:64
4 100:66
4 100:68
4 100:80
8 100:82
8 100:84
8 100:88
16 100:90
``````

and so on.

Even in that reduced set, there are quite a few combinations which generate the same sum/xor, the worst being the large number of possibilities that generate a sum/xor of 255/255, some of which are:

``````255:255=0 255
255:255=1 254
255:255=2 253
255:255=3 252
255:255=4 251
255:255=5 250
255:255=6 249
255:255=7 248
255:255=8 247
255:255=9 246
255:255=10 245
255:255=11 244
255:255=12 243
255:255=13 242
255:255=14 241
255:255=15 240
255:255=16 239
255:255=17 238
255:255=18 237
``````
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It has already been shown that it can't be done, but here are two further reasons why.

For the (rather large) subset of a's and b's `(a & b) == 0`, you have `a + b == (a ^ b)` (because there can be no carries) (the reverse implication does not hold). In such a case, you can, for each bit that is 1 in the sum, choose which one of `a` or `b` contributed that bit. Obviously this subset does not cover the entire input, but it at least proves that it can't be done in general.

Furthermore, there exist many pairs of `(x, y)` such that there is no solution to `a + b == x && (a ^ b) == y`, for example (there are more than just these) all pairs `(x, y)` where `((x ^ y) & 1) == 1` (ie one is odd and the other is even), because the lowest bit of the xor and the sum are equal (the lowest bit has no carry-in). By a simple counting-argument, that must mean that at least some pairs `(x, y)` must have multiple solutions: clearly all pairs of `(a, b)` have some pair of `(x, y)` associated with them, so if not all pairs of `(x, y)` can be used, some other pairs `(x, y)` must be shared.

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