# How can I determine if overflow occured using AND OR NOT and XOR?

I'm trying to use only AND OR XOR and NOT to determine whether adding 2 binary number made of 4 bits will overflow. I know, for example, that something like 1100 + 0100 will wind up as 1 | 0000. But how can I find this using just these logical operators?

I'm trying to get 1000 when overflow happens, and 0000 when it doesn't. This is easy enough since I can just use XOR with a mask to clear the last 3 bits.

Does anyone have suggestions for figuring this out?

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This is entirely language dependant, what are you working with? –  berry120 Jan 26 '11 at 14:52
I'm trying to do this on paper for now. I suppose once I actually figure out how to do it, then I'll move up from there. –  John Jan 26 '11 at 14:58
For now, I'm just trying to figure out (on paper), how to use the operators to detect overflow from adding any two binary numbers. –  John Jan 26 '11 at 15:02
How could it be language dependant if it uses only logical operators... I'm thinking the question, John, will answer if I get it. –  kaoD Jan 26 '11 at 15:02
The best thing I could think of was something along the lines of using a mask of 1111 and XOR to make the 1st number negative, and then using XOR to add that to the 1st number and again to add it to the 2nd number, and then using AND to compare the result to the original 2nd number. If overflow happened, then the resulting bits would be different from the starting bits. (Unfortunately, this doesn't work, so I'm doing something wrong, but I don't see where). –  John Jan 26 '11 at 15:09

I think this will work, using no loops or shifts. But its ugly:

```if (
(a & 0x8) && (b & 0x8) ||
(((a & 0x8) || (b & 0x8)) && ((a & 0x4) && (b & 0x4))) ||
(((a & 0x8) || (b & 0x8)) && ((a & 0x4) || (b & 0x4)) && ((a & 0x2) && (b & 0x2))) ||
(((a & 0x8) || (b & 0x8)) && ((a & 0x4) || (b & 0x4)) && ((a & 0x2) || (b & 0x2)) && ((a & 0x1) && (b & 0x1)))
) {
// overflow
}
```
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Numbers are ABCD and EFGH, ^ is AND, | is OR.

(A^E) | (B^F^(A|E)) | (C^G^(B|F)^(A|E)) | (D^H^(C|G)^(B|F)^(A|E))

I'm sure you can see the pattern there, so a recursive solution is pretty easy for numbers with more bits.

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