On the other hand ...

**Myth 1**: `std::size_t`

is unsigned is because of legacy restrictions that no longer apply.

There are two "historical" reasons commonly referred to here:

`sizeof`

returns `std::size_t`

, which has been unsigned since the days of C.
- Processors had smaller word sizes, so it was important to squeeze that extra bit of range out.

But neither of these reasons, despite being very old, are actually relegated to history.

`sizeof`

still returns a `std::size_t`

which is still unsigned. If you want to interoperate with `sizeof`

or the standard library containers, you're going to have to use `std::size_t`

.

The alternatives are all worse: You could disable signed/unsigned comparison warnings and size conversion warnings and hope that the values will always be in the overlapping ranges so that you can ignore the latent bugs using different types couple potentially introduce. Or you could do a *lot* of range-checking and explicit conversions. Or you could introduce your own size type with clever built-in conversions to centralize the range checking, but no other library is going to use your size type.

And while most mainstream computing is done on 32- and 64-bit processors, C++ is still used on 16-bit microprocessors in embedded systems, even today. On those microprocessors, it's often very useful to have a word-sized value that can represent any value in your memory space.

Our new code still has to interoperate with the standard library. If our new code used signed types while the standard library continues to use unsigned ones, we make it harder for every consumer that has to use both.

**Myth 2**: You don't need that extra bit. (A.K.A., You're never going to have a string larger than 2GB when your address space is only 4GB.)

Sizes and indexes aren't just for memory. Your address space may be limited, but you might process files that are much larger than your address space. And while you might not have a string with more the 2GB, you could comfortably have a bitset with more than 2Gbits. And don't forget virtual containers designed for sparse data.

**Myth 3**: You can always use a wider signed type.

Not always. It's true that for a local variable or two, you could use a `std::int64_t`

(assuming your system has one) or a `signed long long`

and probably write perfectly reasonable code. (But you're still going to need some explicit casts and twice as much bounds checking or you'll have to disable some compiler warnings that might've alerted you to bugs elsewhere in your code.)

But what if you're building a large table of indices? Do you really want an extra two or four *bytes* for every index when you need just one *bit*? Even if you have plenty of memory and a modern processor, making that table twice as large could have deleterious effects on locality of reference, and all your range checks are now two-steps, reducing the effectiveness of branch prediction. And what if you *don't* have all that memory?

**Myth 4**: Unsigned arithmetic is surprising and unnatural.

This implies that *signed* arithmetic is not surprising or somehow more natural. And, perhaps it is when thinking in terms of mathematics where all the basic arithmetic operations are closed over the set of all integers.

But our computers don't work with integers. They work with an infinitesimal fraction of the integers. Our signed arithmetic is not closed over the set of all integers. We have overflow and underflow. To many, that's so surprising and unnatural, they mostly just ignore it.

This is bug:

```
auto mid = (min + max) / 2; // BUGGY
```

If `min`

and `max`

are signed, the sum could overflow, and that yields undefined behavior. Most of us routinely miss this these kinds of bugs because we forget that addition is not closed over the set of signed ints. We get away with it because our compilers typically generate code that does something reasonable (but still surprising).

If `min`

and `max`

are unsigned, the sum could still overflow, but the undefined behavior is gone. You'll still get the wrong answer, so it's still surprising, but not any more surprising than it was with signed ints.

The real unsigned surprise comes with subtraction: If you subtract a larger unsigned int from a smaller one, you're going to end up with a big number. This result isn't any more surprising than if you divided by 0.

Even if you could eliminate unsigned types from all your APIs, you still have to be prepared for these unsigned "surprises" if you deal with the standard containers or file formats or wire protocols. Is it really worth adding friction to your APIs to "solve" only part of the problem?