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I've been working on this puzzle for awhile. I'm trying to figure out how to rotate 4 bits in a number (x) around to the left (with wrapping) by n where 0 <= n <= 31.. The code will look like:

moveNib(int x, int n){
//... some code here

The trick is that I can only use these operators:

~ & ^ | + << >>

and of them only a combination of 25. I also can not use If statements, loops, function calls. And I may only use type int.

An example would be moveNib(0x87654321,1) = 0x76543218.

My attempt: I have figured out how to use a mask to store the the bits and all but I can't figure out how to move by an arbitrary number. Any help would be appreciated thank you!

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Are you trying to pick a nibble in the number and rotate it, or are you trying to rotate the whole number by multiples of 1 nibble? –  user2357112 Mar 2 '14 at 2:47
What do you mean by "a combination of 25"? Also, are you sure - isn't on the list of allowed operators? If not, it can easily be emulated via ~ and + assuming a two's complement architecture, but it seems odd to allow + but not -. –  amaurea Mar 2 '14 at 2:47
Why is moveNib(0x87654321,1) supposed to return 0x76543218? –  user2357112 Mar 2 '14 at 2:49
user: That would be consistent with rotating the nibbles one step to the left. –  amaurea Mar 2 '14 at 2:50
@user2357112 It's rather obvious; no guessing needed. Your first post posed two alternatives, one of which 0x76543218 satisfies and the other of which it doesn't. It's also clear from the description and the name of the function -- rotating a nibble in place wouldn't be called "move", and it would require an additional parameter so as to specify both which nibble and how many bits to rotate by. –  Jim Balter Mar 2 '14 at 3:01

2 Answers 2

up vote 3 down vote accepted

How about:

uint32_t moveNib(uint32_t x, int n) { return x<<(n<<2) | x>>((8-n)<<2); }

It uses <<2 to convert from nibbles to bits, and then shifts the bits by that much. To handle wraparound, we OR by a copy of the number which has been shifted by the opposite amount in the opposite direciton. For example, with x=0x87654321 and n=1, the left part is shifted 4 bits to the left and becomes 0x76543210, and the right part is shifted 28 bits to the right and becomes 0x00000008, and when ORed together, the result is 0x76543218, as requested.

Edit: If - really isn't allowed, then this will get the same result (assuming an architecture with two's complement integers) without using it:

uint32_t moveNib(uint32_t x, int n) { return x<<(n<<2) | x>>((9+~n)<<2); } 

Edit2: OK. Since you aren't allowed to use anything but int, how about this, then?

int moveNib(int x, int n) { return (x&0xffffffff)<<(n<<2) | (x&0xffffffff)>>((9+~n)<<2); }

The logic is the same as before, but we force the calculation to use unsigned integers by ANDing with 0xffffffff. All this assumes 32 bit integers, though. Is there anything else I have missed now?

Edit3: Here's one more version, which should be a bit more portable:

int moveNib(int x, int n) { return ((x|0u)<<((n&7)<<2) | (x|0u)>>((9+~(n&7))<<2))&0xffffffff; }

It caps n as suggested by chux, and uses |0u to convert to unsigned in order to avoid the sign bit duplication you get with signed integers. This works because (from the standard):

Otherwise, if the operand that has unsigned integer type has rank greater or equal to the rank of the type of the other operand, then the operand with signed integer type is converted to the type of the operand with unsigned integer type.

Since int and 0u have the same rank, but 0u is unsigned, then the result is unsigned, even though ORing with 0 otherwise would be a null operation.

It then truncates the result to the range of a 32-bit int so that the function will still work if ints have more bits than this (though the rotation will still be performed on the lowest 32 bits in that case. A 64-bit version would replace 7 by 15, 9 by 17 and truncate using 0xffffffffffffffff).

This solution uses 12 operators (11 if you skip the truncation, 10 if you store n&7 in a variable).

To see what happens in detail here, let's go through it for the example you gave: x=0x87654321, n=1. x|0u results in a the unsigned number 0x87654321u. (n&7)<<2=4, so we will shift 4 bits to the left, while ((9+~(n&7))<<2=28, so we will shift 28 bits to the right. So putting this together, we will compute 0x87654321u<<4 | 0x87654321u >> 28. For 32-bit integers, this is 0x76543210|0x8=0x76543218. But for 64-bit integers it is 0x876543210|0x8=0x876543218, so in that case we need to truncate to 32 bits, which is what the final &0xffffffff does. If the integers are shorter than 32 bits, then this won't work, but your example in the question had 32 bits, so I assume the integer types are at least that long.

As a small side-note: If you allow one operator which is not on the list, the sizeof operator, then we can make a version that works with all the bits of a longer int automatically. Inspired by Aki, we get (using 16 operators (remember, sizeof is an operator in C)):

int moveNib(int x, int n) {
    int nbit = (n&((sizeof(int)<<1)+~0u))<<2;
    return (x|0u)<<nbit | (x|0u)>>((sizeof(int)<<3)+1u+~nbit);
share|improve this answer
8-n will produce a negative result when n > 8. OP explicitly allowed that. I don't think this is enough reason for a downvote, though. –  dasblinkenlight Mar 2 '14 at 2:53
That's why I used unsigned integers rather than signed ones. I've tested the function, and it works for numbers larger than 8 too (as well as negative values of n). I would also like to know the reason for the downvote. –  amaurea Mar 2 '14 at 2:55
"And I may only use type int." –  Nikita Kouevda Mar 2 '14 at 2:56
Assuming 32-bit int, shifts greater than 31 are not well defined even if they work as desired on your machine. Suggest rather than n, use (n&7). –  chux Mar 2 '14 at 4:43
@Shaw I have edited my answer with more details now. I still don't understand why it doesn't work for you. I have both tested it on my own computer and checked the standard to see that it should work on any computer two's complement integers. I would be very interested in hearing what you get for each of the steps in the detailed example I gave. –  amaurea Mar 3 '14 at 10:53

Without the additional restrictions, the typical rotate_left operation (by 0 < n < 32) is trivial.

uint32_t X = (x << 4*n) | (x >> 4*(8-n));

Since we are talking about rotations, n < 0 is not a problem. Rotation right by 1 is the same as rotation left by 7 units. Ie. nn=n & 7; and we are through.

int nn = (n & 7) << 2;                         // Remove the multiplication
uint32_t X = (x << nn) | (x >> (32-nn));

When nn == 0, x would be shifted by 32, which is undefined. This can be replaced simply with x >> 0, i.e. no rotation at all. (x << 0) | (x >> 0) == x.

Replacing the subtraction with addition: a - b = a + (~b+1) and simplifying:

int nn = (n & 7) << 2;
int mm = (33 + ~nn) & 31;
uint32_t X = (x << nn) | (x >> mm);    // when nn=0, also mm=0

Now the only problem is in shifting a signed int x right, which would duplicate the sign bit. That should be cured by a mask: (x << nn) - 1

int nn = (n & 7) << 2;
int mm = (33 + ~nn) & 31;
int result = (x << nn) | ((x >> mm) & ((1 << nn) + ~0));

At this point we have used just 12 of the allowed operations -- next we can start to dig into the problem of sizeof(int)...

int nn = (n & (sizeof(int)-1)) << 2; // etc.
share|improve this answer
sizeof isn't on the list of allowed operators, though... –  amaurea Mar 3 '14 at 10:53
No, it's not. OTOH it's not necessary to calculate that, since the problem description defines sizeof int == 4. –  Aki Suihkonen Mar 3 '14 at 11:06
Or rather, the examples given in the problem show that the rotation should happen on only the least significant 4 bytes of the number, which isn't quite the same (it's why I truncate to 32 bits in the end). –  amaurea Mar 3 '14 at 11:22

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