For the built-in
!= operator, or an overload taking at least the first argument by value (i.e.
operator !=(T, T)):
This is UB per [intro.execution]/10:
Except where noted, evaluations of operands of individual operators and of subexpressions of individual expressions are unsequenced.
[...] If a side effect on a memory location is unsequenced relative to either another side effect on the same memory location or a value computation using the value of any object in the same memory location, and they are not potentially concurrent, the behavior is undefined.
!= operator does not have any special sequencing properties.)
!= is overloaded for
v's type does not affect sequencing rules (since you're not calling it using function call notation) ([over.match.oper]/2):
[...] the operator notation is first transformed to the equivalent function-call notation [...] However, the operands are sequenced in the order prescribed for the built-in operator.
(And even if you did use the function call notation, the operands would still be indeterminately sequenced, meaning no UB but no guarantee of consistent results either.)
In the case of an overload taking the operands by reference (such as
operator !=(const T&, const T&) or
T::operator !=(const T&) const):
The behavior is well-defined.
Binding a reference (directly) does not access the object (as in the case of
v in your example), nor does calling a member function on it, so there's no conflict between the two operands. And the access that happens in the body of the function (the actual comparison) is sequenced after the initialization of its parameters ([intro.execution]/11):
When calling a function [...], every value computation and side effect associated with any argument expression [...] is sequenced before execution of every expression or statement in the body of the called function.
Which also means that the comparison will always take place after the side effects of both operands. In your example this means you'll always be comparing the post-exchange value of
v to the value returned by
v's previous one).
The above is true before C++17 as well, though for slightly different reasons.
In C++14, as opposed to C++17 ([expr]/2):
Overloaded operators obey the rules for syntax specified in Clause [expr], but the requirements of [...] evaluation order are replaced by the rules for function call.
...but the arguments in a function call are themselves unsequenced as opposed to indeterminately sequenced ([expr.call]/8):
The evaluations of the postfix expression and of the arguments are all unsequenced relative to one another.
(These quotes are from non-normative notes but they illustrate the point well.)
Which means the effect is still the same: operands are unsequenced, UB in the case where evaluating
v accesses its value, well-defined otherwise. The only difference is that explicitly using function call syntax in the first case does not prevent UB.