Here's my solution, but even more importantly my approach to solving the problem.

I approached the problem by

- drawing the memory cells and drawing arrows from the destination to the source.
- made a table showing the above drawing.
- labeling each row in the table with the relative byte address.

This showed me the pattern:

- let
`iL`

be the low nybble (half byte) of `a[i]`

- let
`iH`

be the high nybble of `a[i]`

`iH = (i+1)L`

`iL = (i+2)H`

This pattern holds for all bytes.

Translating into C, this means:

```
a[i] = (iH << 4) OR iL
a[i] = ((a[i+1] & 0x0f) << 4) | ((a[i+2] & 0xf0) >> 4)
```

We now make three more observations:

- since we carry out the assignments left to right, we don't need to store any values in temporary variables.
- we will have a special case for the tail: all
`12 bits`

at the end will be zero.
- we must avoid reading undefined memory past the array. since we never read more than
`a[i+2]`

, this only affects the last two bytes

So, we

- handle the general case by looping for
`N-2 bytes`

and performing the general calculation above
- handle the next to last byte by it by setting
`iH = (i+1)L`

- handle the last byte by setting it to
`0`

given `a`

with length `N`

, we get:

```
for (i = 0; i < N - 2; ++i) {
a[i] = ((a[i+1] & 0x0f) << 4) | ((a[i+2] & 0xf0) >> 4);
}
a[N-2] = (a[N-1) & 0x0f) << 4;
a[N-1] = 0;
```

And there you have it... the array is shifted left by `12 bits`

. It could easily be generalized to shifting `N bits`

, noting that there will be `M`

assignment statements where `M = number of bits modulo 8`

, I believe.

The loop could be made more efficient on some machines by translating to pointers

```
for (p = a, p2=a+N-2; p != p2; ++p) {
*p = ((*(p+1) & 0x0f) << 4) | (((*(p+2) & 0xf0) >> 4);
}
```

and by using the largest integer data type supported by the CPU.

(I've just typed this in, so now would be a good time for somebody to review the code, especially since bit twiddling is notoriously easy to get wrong.)