Tow 32 bit integer values A and B, are processed to give the 32 bit integers C and D as per the following rules. Which of the rule(s) is(are) reversible? i.e. is it possible to obtain A and B given c and D in all condition?

A. C = (int32)(A+B), D = (int32)(A-B)

B. C = (int32)(A+B), D= (int32)((A-B)>>1)

C. C = (int32)(A+B), D = B

D. C = (int32)(A+B), D = (int32)(A+2*B)

E. C = (int32)(A*B), D = (int32)(A/B)

A few questions about the integer arithmetic. Modular addition forms amathematical structure known as an *abelian group*. **How about signed addition?** It's also commutative (that’s where the “abelian” part comes in) and associative, **is this forms a n an abelian group**?

Given that integer addition is commutative and associative, C is apparently true, because we can retrieve A by (A+(B-B)). **What about D?** Can we assume that `2 * B = B + B`

st. `B = A+B+B-(A+B)`

?

And multiplication is more complicated, but I know that it can not be retrieve A if there is an overflow.

`unsigned`

integer types form groups with respect to addition in C and C++. Signed addition usually can't, already for the simple reason that`INT_MIN`

usually has no inverse in the common 2complement representation. – Jens Gustedt Oct 6 '13 at 7:44`INT32_MIN`

for`A`

and`B`

and it is implementation defined what will happen in any case, so there is no answer. I get the suspicion that you are trying to get a consistent answer to an ill-posed exercise. Often we see such exercise here that come from not-so-well-informed teachers that take two's complement for granted and never heard of signals that can be raised in case of overflow. Don't do such stuff with`int32`

(BTW the standard`typedef`

is called`int32_t`

) but with`uint32_t`

. Where do you have these questions from? – Jens Gustedt Oct 6 '13 at 18:58Microsoft intern hiring written test. But I've seen it somewhere else. – zoujyjs Oct 8 '13 at 3:33`E = C - D = A + B - B = A`

and B by`C - E`

. What do you think? And I take D as a right answer, see my questions. – zoujyjs Oct 8 '13 at 3:38