# Moving a bit within a byte using bitfield or bitwise operators

Is there an elegant way of moving a bit within a byte (or word/long). For simplicity, lets use a simple 8-bit byte and just one bit to move within the byte.

Given a bit number, based on 0-7 Least-sig-bit to most-sig-bit, (or bits 1-8 if you'd rather), I would like to move a bit from one position to another:

``````7654 3210 <bit position
0101 1010 <some binary value
--x- --y- <move bit from x to y
0111 0100 <new value with x moved to y and intervening bits shifted left
``````

So, x at bit position 5 moves to y at bit position 1, bits 0,6,7 stay unchanged. Bits 2,3,4 are shifted left to 'make room' for the bit moved from 5 to 2. This is just an example.

It is important that the bit moves, not swapped with its target. There are numerous exampls of bits that swap, but that is quite trivial.

The solution ideally would use simple bit-twiddling and bitwise operators. Assume language agnostic, bit simple AND/OR/XOR, NOT, SHIFT Left/Right / ROTATE or similar instructions would be fine in any combination, plus any other basic arithmetic operator, eg: mod, addition/subtraction etc. Even working psuedo-code would be ok. Alternatively, a bit array or bitfield type structure would probably be straightforward.

In addition to the actual bit move, I would like to find a way to :

• Move any bit up or down.
• Specify the bit number source/destination in any convenient format: eg: 6>2 implies shift down, 3>7 shift up or start-bit +/- offset: 6-4 or 3+4, or bit weighted: bit 6=64 to bit 3=8.
• Possibly extendable from byte to unsigned int, long, etc.
• (Ideally, be extendable to more than one bit at a time, probably adjacent bits if easier)

Performance is not a major issue, but something elegant is likley to be plenty fast enough.

My own niaive approach would be to identify the source and target bit positions, decide if shift up or down, take a shifted copy, mask off the static bits and find the source bit, merge the static and shifted bits and somehow set/clear the target bit. However, while the theory seems good, an elegant implementation is beyond me.

I realise that a precompiled lookup table could be built for a byte, but if this is to be extended to integers/longs, this would be impractical for me.

Any help appreciated. Thanks in advance.

-
FWIW the PowerPC ISA has some great instructions for doing this kind of thing (bit field manipulation). Otherwise it's not hard to do with shift and mask operations in an HLL. –  Paul R Jun 21 '11 at 20:34
I know it doesn't look hard, but a lot harder/inelegant to actually do in practice. If HLL=High-Level-Lang, then even so, apart from bitfield and boolean arrays, I still don't have a nice solution. –  andora Jun 21 '11 at 20:49
Bit twiddling is rarely elegant. Making it elegant generally means hiding it behind a function (or possibly a macro). –  Chris Lutz Jun 21 '11 at 21:11
@chris: Hmmm, maybe, it depends on the support provided by the language. In my app, I won't be using C or similar, so something that can be done in Assembler or basic bitwise is a bonus. Bitfields/Arrays/structures etc are ok, but its nice to know (for me anyway) whats going on under the hood. Mathews answer looks pretty good to me (ie: elegant) and suits me perfectly. –  andora Jun 24 '11 at 14:24

First, an observation about the original problem, and the subsequent extensions that you mention:

The "moving a bit" operation that you describe is really a rotation of a contiguous range of bits. In your example, you are rotating bits 1-5 inclusive, by one bit to the left:

``````  7   6   5   4   3   2   1   0          7   6   5   4   3   2   1   0
+---+---+---+---+---+---+---+---+      +---+---+---+---+---+---+---+---+
| 0 | 1 | 0<--1<--1<--0<--1 | 0 |  ->  | 0 | 1 | 1 | 1 | 0 | 1 | 0 | 0 |
+---+---+-|-+---+---+---+-^-+---+      +---+---+---+---+---+---+---+---+
|               |
+---------------+
``````

If you consider a more general form of this operation to be "rotate a range of bits left by some amount" with three parameters:

1. the least significant bit to include in the rotation
2. the most significant bit to include in the rotation
3. the number of bits to rotate by

then it becomes a single basic primitive which can perform all of the things you want to do:

• you can obviously move any bit (choose appropriate least/most significant bit paramaters);
• you can rotate left or right, because if you are rotating a range of n bits, then a rotation right by k bits is the same thing as a rotation left by n - k bits;
• it trivially generalises to any bit width;
• by definition we can rotate more by more than one bit at a time.

So now, all that's needed is to construct this primitive...

We can form a mask for bits 0 - n by shifting a 1 by n + 1 bits to the left, then subtracting 1. e.g. a mask for bits 0-5 would be (in binary):

``````00111111
``````

...which can be formed by taking a 1:

``````00000001
``````

...shifting 5+1 = 6 bits to the left:

``````01000000
``````

...and subtracting 1 to give:

``````00111111
``````

In C, this would be `(1 << (bit + 1)) - 1`. But there is a subtlety here, for C at least (and I apologise for the digression when you've tagged this as language-agnostic, but this is important, and there are probably similar issues in other languages too): a shift by the width of your type (or more) leads to undefined behaviour. So if we were trying to construct a mask for bits 0-7 for an 8-bit type, the calculation would be `(1 << 8) - 1`, which would be undefined. (It might work on some systems and some compilers, but wouldn't be portable.) There are also undefined behaviour issues with signed types in the case where you would end up shifting into the sign bit.

Fortunately, in C, we can avoid these problems by using an `unsigned` type, and writing the expression as `(1 << bit) + (1 << bit) - 1`. Arithmetic with unsigned n-bit values is defined by the standard to be reduced modulo 2n, and all of the individual operations are well-defined, so we're guaranteed to get the right answer.

(End of digression.)

OK, so now we have a mask for bits 0 - msb. We want to make a mask for bits lsb - msb, which we can do by subtracting the mask for bits 0 - (lsb-1), which is `(1 << lsb) - 1`. e.g.

``````  00111111      mask for bits 0-5:  (1 << 5) + (1 << 5) - 1
- 00000001      mask for bits 0-0:  (1 << 1) - 1
--------                         -------------------------------
00111110      mask for bits 1-5:  (1 << 5) + (1 << 5) - (1 << 1)
``````

So the final expression for the mask is:

``````mask = (1 << msb) + (1 << msb) - (1 << lsb);
``````

The bits to be rotated can be selected by a bitwise AND with the mask:

``````to_rotate = value & mask;
``````

...and the bits that will be left untouched can be selected by a AND with the inverted mask:

``````untouched = value & ~mask;
``````

The rotation itself can be performed easily in two parts: first, we can obtain the leftmost bits of the rotated portion by simply rotating `to_rotate` left and discarding any bits that fall outside the mask:

``````left = (to_rotate << shift) & mask;
``````

To get the rightmost bits, rotate `to_rotate` right by (n - shift) bits, where n is the number of bits we're rotating (this n can be calculated as `msb + 1 - lsb`):

``````right = (to_rotate >> (msb + 1 - lsb - shift)) & mask;
``````

The final result can be obtained by combining all the bits from `untouched`, `left`, and `right`:

``````result = untouched | left | right;
``````

Your original example would work like this (`msb` is 5, `lsb` is 1, and `shift` is 1):

``````    value = 01011010

mask  = 00111110   from (1 << 5) + (1 << 5) - (1 << 1)

01011010   value
----------
to_rotate = 00011010

01011010   value
----------
untouched = 01000000

00110100   to_rotate << 1
----------
left = 00110100

00000001   to_rotate >> 4  (5 + 1 - 1 - 1 = 4)
----------
right = 00000000

01000000   untouched
00110100   left
| 00000000   right
----------
result = 01110100
``````

Here's a different example with a 16-bit input value, `msb` = 15, `lsb` = 4, and `shift` = 4 (which rotates the top 3 hex digits of a 4-digit hex value):

``````    value = 0101011001111000   (0x5678)

mask  = 1111111111110000   from (1 << 15) + (1 << 15) - (1 << 4)

0101011001111000   value
------------------
to_rotate = 0101011001110000

0101011001111000   value
------------------
untouched = 0000000000001000

0110011100000000   to_rotate << 4
------------------
left = 0110011100000000

0000000001010110   to_rotate >> 8  (15 + 1 - 4 - 4 = 8)
------------------
right = 0000000001010000

0000000000001000   untouched
0110011100000000   left
| 0000000001010000   right
------------------
result = 0110011101011000   =  0x6758
``````
-
Mathew: what a great answer and examples. Thank you for taking the time out to detail the process. Shame I can only give you 1 upvote, but but am happy to accept this as the answer. (Just one minor nit-pick, in the 16bit example, the final stage shows untouched with a bit set at pos14 that should be clear) –  andora Jun 24 '11 at 14:11
You're welcome; and thanks for spotting the mistake - I've fixed it now! –  Matthew Slattery Jun 24 '11 at 19:40

Are you using bits to conserve space? Is it REALLY needed?

You might be better off with a list class that allows you to remove and insert items in the list. In your case the items would be Booleans.

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No, nothing to do with space constraints, and yes, REALLY wanted (!) just general bit manipulation possibly applicable to encoding. Figured I could parse out to an array of booleans, re-arrange and blend back to a byte, but doesn't strike me me as very elegant. Thanks for the answer thou. –  andora Jun 21 '11 at 20:24

This likely doesn't qualify as "elegant," but you might be able to cram it into one line if that is your kind of thing? The plan is to split the number into four pieces (shouldn't be hard with bit operations, right?), do the appropriate things to them, and then put the three pieces back together.

``````              Number: 01x1 10y1
P1 (before x): 0100 0000
P2 (just bit x): 00x0 0000
P3 (between x and y): 0001 10y0
P4 (after y): 0000 0001
``````

Then the number you want is `[P1] + [P3 shifted up by 1] + [P2 shifted down by 4] + [P4]`.

``````                  P1: 0100 0000
P2 shifted down by 3: 0000 00x0
P3 shifted up by 1: 0011 0y00
P4: 0000 0001

Sum: 0111 0yx1
``````
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Just for clarification, x moves to replace the bit at position y, so P3 includes y and the y bit moves up/left to move out of the way. I get your drift thou, the 'tricky part' is specifying the bit numbers/positions in such a way as to choose P1,P2,P3 & P4. –  andora Jun 21 '11 at 20:59
If you think of `something AND 0011 1111 1111` as chopping off the end of a number, and `something MOD 0100 0000 0000` as doing the opposite, you can make P1, P2, P3, and P4 using AND and MOD... it works. But this isn't "elegant," and I wanted an elegant answer too, which is why I upvoted your question. :) –  Chris Cunningham Jun 21 '11 at 21:21
I was thinking along similar lines and that you can derive P3 from XOR of the start/end bits, then use P3 as a mask against the shifted P3 part. Interesting +1 Thanks !! –  andora Jun 21 '11 at 22:14

Here's a working implementation in C that is not highly optimised but which might at least serve as a starting point for any further implementations. It works with ints but you can adapt it for any word size, or just use it as is and mask out any unwanted high order bits (e.g. if you are working with individual bytes). I broke the functionality down into two lower level routines for extracting a bit and inserting a bit - these may have other uses, I imagine.

``````//
// bits.c
//

#include <stdio.h>
#include <stdlib.h>

//
// extract_bit
//
// extract bit at given index and move less significant bits left
//

int extract_bit(int *word, int index)
{
int result = (*word & (1 << index)) != 0;
int mask = (1 << index) + (1 << index) - 1;
return result;
}

//
// insert_bit
//
// insert bit at given index and move less significant bits right
//

void insert_bit(int *word, int index, int val)
{
int mask1 = (1 << index) + (1 << index) - 1;
int mask2 = (1 << index) - 1;
*word = ((*word >> 1) & mask2) | (*word & ~mask1) | (val << index);
}

//
// move_bit
//
// move bit from given src index to given dest index
//

int move_bit(int *word, int src_index, int dest_index)
{
int val = extract_bit(word, src_index);
insert_bit(word, dest_index, val);
return val;
}

int main(int argc, char * argv[])
{
if (argc > 2)
{
int test = 0x55555555;
int index1 = atoi(argv[1]);
int index2 = atoi(argv[2]);

printf("test (before) = %#x\n", test);
printf("index (src) = %d\n", index1);
printf("index (dest) = %d\n", index2);

move_bit(&test, index1, index2);

printf("test (after) = %#x\n", test);
}

return 0;
}
``````
-
Interesting - thanks. Need to look at this in detail but just wonder if shift-right needed? I think that LSB will be static, and moved bit should move next to LSB bits, (if shift-down) and only shift-left needed? –  andora Jun 21 '11 at 22:20
It's not really fully optimised - extract_bit will shift (some) LS bits up one if needed and insert_bit will shift (some) LS bits down again if needed. It might seem inefficient, and no doubt you could condense this down into a single routine, but I suspect you would need additional logic to handle edge cases and there might well still be two shifts needed in some cases. –  Paul R Jun 21 '11 at 22:24
Thanks Paul. I see you give many of the details of process covered in Mathews answer first, but I think he gave a better answer overall, including the way to shift more than 1 bit. Upvote by way of appreciation. –  andora Jun 24 '11 at 14:16