It is not possible, since it would not make any sense.
Your code will obtain valid values for the comparison, but it gives very little guarantees on when those values are obtained. So if the check succeeds, all you'll know is that
readIdx was at some point in time equal to a value that
writeIdx + 1 yielded at some point in time. These two points in time are mostly unrelated. In particular, it is allowed that at no single point in time the value of
readIdx was equal to the value of
writeIdx + 1 but still the check succeeds.
Here's why this is not really a problem: You won't be able to establish the concept of both atomics being equal at the same time without introducing an additional lock. The problem is that whatever code depends on that condition needs to be part of the same atomic block of execution that performs the check. If it is not, the condition might change before the code finishes executing.
On the other hand, if no part of the code depends on the condition, it makes no sense to introduce it as a concept in the first place.
So here's how to continue: Go back and reevaluate whether you really have code that depends on the condition that both variables have to have the expected values at the time that code executes. If that is a case, you'll need to protect that code with a lock. If not, it is likely that you don't need to check the condition at all, as the guarantees given by your current code are probably too weak to be of any real use.