Branches like these are typically not expensive. They usually are implemented using predication. That is, the GPU computes both branches but only actually stores the results of the instructions where the predication condition is true. Hence no jump instruction is used. Here's what the assembly code could look like:
cmp_eq p0, r0, 0.0 // predicate = (value == 0.0)
(p0) mov r1, 0.0 // other_value = 0.0, if predicate true
(!p0) rcp r1, r0 // other_value = 1.0 / value, if predicate false
Note that in this case the second instruction doesn't actually have to be predicated. Anyway, as indicated by others the result of the division (reciprocal) is undefined when the denominator is zero. But as you can see you should be able to get well-defined behavior at the cost of just a couple of cheap instructions (division is typically slow). To my knowledge all GPUs that support real branches (jump instructions) also support predication. The shader compiler will evaluate whether to use predication or a jump, and will usually do the right thing.
Of course if you really don't care about the result of a division by zero then you can save any and all cost of predication.