I am facing a rather peculiar problem. I am working on a compiler for an architecture that doesn't support bitwise operations. However, it handles signed 16-bit integer arithmetics and I was wondering if it would be possible to implement bitwise operations using only:

**Addition**(*c = a + b*)**Subtraction**(*c = a - b*)**Division**(*c = a / b*)**Multiplication**(*c = a***b*)**Modulus**(*c = a % b*)**Minimum**(*c = min(a, b)*)**Maximum**(*c = max(a, b)*)**Comparisons**(*c = (a < b), c = (a == b), c = (a <= b), et.c.*)**Jumps**(*goto, for, et.c.*)

The bitwise operations I want to be able to support are:

**Or**(*c = a | b*)**And**(*c = a & b*)**Xor**(*c = a ^ b*)**Left Shift**(*c = a << b*)**Right Shift**(*c = a >> b*)- (All integers are signed so this is a problem)
**Signed Shift**(*c = a >>> b*)**One's Complement**(*a = ~b*)- (Already found a solution, see below)

Normally the problem is the other way around; how to achieve arithmetic optimizations using bitwise hacks. However not in this case.

Writable memory is **very scarce** on this architecture, hence the need for bitwise operations. The bitwise functions themselves should not use a lot of temporary variables. However, constant read-only data & instruction memory is abundant. A side note here also is that jumps and branches are not expensive and all data is readily cached. Jumps cost half the cycles as arithmetic (including load/store) instructions do. On other words, all of the above supported functions cost twice the cycles of a single jump.

## Some thoughts that might help:

I figured out that you can do **one's complement** (negate bits) with the following code:

```
// Bitwise one's complement
b = ~a;
// Arithmetic one's complement
b = -1 - a;
```

I also remember the old shift hack when dividing with a power of two so the **bitwise shift** can be expressed as:

```
// Bitwise left shift
b = a << 4;
// Arithmetic left shift
b = a * 16; // 2^4 = 16
// Signed right shift
b = a >>> 4;
// Arithmetic right shift
b = a / 16;
```

For the rest of the bitwise operations I am slightly clueless. I wish the architects of this architecture would have supplied bit-operations.

I would also like to know if there is a fast/easy way of computing the power of two (for shift operations) without using a memory data table. A naive solution would be to jump into a field of multiplications:

```
b = 1;
switch (a)
{
case 15: b = b * 2;
case 14: b = b * 2;
// ... exploting fallthrough (instruction memory is magnitudes larger)
case 2: b = b * 2;
case 1: b = b * 2;
}
```

Or a Set & Jump approach:

```
switch (a)
{
case 15: b = 32768; break;
case 14: b = 16384; break;
// ... exploiting the fact that a jump is faster than one additional mul
// at the cost of doubling the instruction memory footprint.
case 2: b = 4; break;
case 1: b = 2; break;
}
```

veryscarce (about 40 bytes) per robot, and I wanted to write a high level compiler that also could supply a slightly expensive bitpacker to squeeze more info in there. Constant memory & tables can be simulated through data banks containing SET operands. A game for coders!7more comments