Stepanov gives the following definition of value semantics (which he calls a Regular Type)

```
T a = b; assert(a == b); // 1
T a; a = b; assert(a == b); // 2
T a = c; T b = c; a = d; assert(b == c); // 3
T a = c; T b = c; zap(a); assert(b == c && a != b); // 4
```

I.e., types having value semantics are DefaultConstructible, CopyConstructible, Assignable and EqualityComparible (properties 1 and 2). Furthermore,

after assigning the same value `c`

to both `a`

and `b`

, we expect
to be able to modify `a`

without changing the value of `b`

(property
3). If `zap`

is an operation which always changes the value of its
operand, we expect that `b`

and `c`

do not continue to be equal simply
because their values were changed along with `a`

’s, but rather because
changing `a`

’s value did not change theirs (property 4).

Types with reference semantics can obey 1 and 2, but not 3 and 4 (i.e. modifications to one of more objects which point to or reference the same value, affect all of them).

All the built-in types obey value semantics and modifications are localized. This makes them e.g. very suited for pure functions and parallel programming. With reference semantics (e.g. of objects with virtual functions), changes are not localized anymore.

```
T* a = c; T* b = c; a = d; assert(b == d); // 5
T* a = c; T* b = c; zap(a); assert(b != c && a == b); // 6
```