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:

- the least significant bit to include in the rotation
- the most significant bit to include in the rotation
- 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...

To start with, we're almost certainly going to need a bit mask for the bits we care about.

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 2^{n}, 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
& 00111110 mask
----------
to_rotate = 00011010
01011010 value
& 11000001 ~mask (i.e. inverted mask)
----------
untouched = 01000000
00110100 to_rotate << 1
& 00111110 mask
----------
left = 00110100
00000001 to_rotate >> 4 (5 + 1 - 1 - 1 = 4)
& 00111110 mask
----------
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
& 1111111111110000 mask
------------------
to_rotate = 0101011001110000
0101011001111000 value
& 0000000000001111 ~mask
------------------
untouched = 0000000000001000
0110011100000000 to_rotate << 4
& 1111111111110000 mask
------------------
left = 0110011100000000
0000000001010110 to_rotate >> 8 (15 + 1 - 4 - 4 = 8)
& 1111111111110000 mask
------------------
right = 0000000001010000
0000000000001000 untouched
0110011100000000 left
| 0000000001010000 right
------------------
result = 0110011101011000 = 0x6758
```