The key intuitive aspect that distinguishes **XOR** from the other logical operators is that it is *lossless*, or *non-lossy*, meaning that, unlike **AND**, and **OR** (and more similar to **NOT** in this regard), it is deterministcally reversible: You can exactly recover one of the input values given the rest of the computation history.

The following diagrams illustrate that **AND** and **OR** each have at least one case where the state of one of the inputs is irrecoverable, given a certain value of the other input. I indicate these as "lost" inputs.

For the **XOR** gate, there is no condition in which an input or output value cannot be recovered, given the rest of the computation history. In fact, there's a symmetry that knowing *any two values* of the triple `(in0, in1, out)`

allows you to recover the third. In other words, regardless of input or output, each of these three values is the **XOR** of the other two!

This picture suggests that another way to think of the **XOR** operation is as a **controllable NOT** gate. By toggling one of the inputs (the upper one in the example above), you can control whether or not the other (lower) one is negated.

Yet another equivalent view is that **XOR** implements the positive-logic **not-equals** (≠) function with respect to its two inputs. And thus also the **equals** function (=) under negative-logic.

In accordance with its symmetry and information-preserving properties, **XOR** should come to mind for problems that require reversibility or perfect data recovery. The most obvious example is that **XOR**ing a dataset with a constant 'key' trivially obscures the data such that knowing the key (which might be kept "secret"), allows for exact recovery.

Preserving all of the available information is also desirable in hashing. Because you want hash values that maximally discriminate amongst the source items, you want to make sure that as many of their distinguishing characteristics as possible are incorporated, minimizing loss, in the hash code. For example, to hash a 64-bit value into 32 bits, you would use the programming language **XOR** operator `^`

because it's an easy way to guarantee that each of the 64 input bits has an opportunity to influence the output:

```
uint GetHashCode(ulong ul)
{
return (uint)ul ^ (uint)(ul >> 32);
}
```

Note that in this example, information is lost even though **XOR** was used. (In fact, ‘strategic information loss’ is kind of the whole point of hashing). The original value of `ul`

is not recoverable from the hash code, because with that value alone you don't have two out of the three 32-bit values that were used in the internal computation. Recall from above that you need to retain any two out of the three values for perfect reversal. Out of the resulting hash code and the two values that were **XOR**ed, you may have saved the result, but typically do not save either of the latter to use as a key value for obtaining the other.^{1}

As an amusing aside, **XOR** was uniquely helpful in the days of bit-twiddling hacks. My contribution back then was a way to **Conditionally set or clear bits without branching** in C/C++:

```
unsigned int v; // the value to modify
unsigned int m; // mask: the bits to set or clear
int f; // condition: 0 to 'set', or 1 to 'clear'
v ^= (-f ^ v) & m; // if (f) v |= m; else v &= ~m;
```

On a more serious note, the fact that **XOR** is non-lossy has important information-theoretical implications for futuristic computing, due to an important relationship between information processing and the Second Law of Thermodynamics. As explained in an excellent and accessible book by Charles Seife, *Decoding the Universe*, it turns out that the loss of information during computation has an *e̲x̲a̲c̲t̲* mathematical relationship with the black-body radiation emanated by a processing system. Indeed, the notion of entropy plays a central role in quantifying how information "loss" is (re-)expressed as heat (this also being the same prominent relation from Steven Hawking's famous black hole wager).

Such talk regarding **XOR** is not necessarily a stretch; Seife notes that modern CPU development currently faces fundamental toleration limitations on the **watts/cm²** of semiconducting materials, and that a solution would be to design reversible, or lossless, computing systems. In this speculative future-generation of CPUs, **XOR**'s ability to preserve information—*and thus shunt away heat*—would be invaluable for increasing computational density (i.e., MIPS/per cm²) despite such materials limitations.

^{1. In this simple example, the relevant 3 values would be the hash code plus the upper- and lower-parts of the original ulong value. Of course the original hashed 'data' itself, represented by ul here, likely is retained.}
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