The question is how many objects are eligible for garbage collection right before
// Some other code.
The question is nonsensical.
Garbage collectors act at run-time on the information available there. Reachability is determined by the global roots stored in registers, on the thread stacks and in global variables. The contents of registers and the stacks are the culmination of many stages of compilation that completely mangle the code. The concepts of lexical scope and line numbers from the source code no longer exist so it is nonsensical to ask questions about what the GC might see at certain points in the source code because those points do not exist in the world of the GC.
So we must first assume a direct correspondence between the source code and the generated code or we cannot even make sense of the point in the code that the question refers to. I cannot think of any working VM that actually does this in practice and, in fact, Java probably has high-level language constructs that cannot even be compiled to bytecode in this way.
Next, we must assume a model for the way local references are kept on the stack. Rather than assuming some ill-defined model in order to derive a random answer I'm going to show that the choice of model allows us to arrive at answers ranging from "nothing is eligible for GC" to "everything is eligible for GC". This full range of justifiable answers really highlights just how bad that question is.
Consider a simple model where intermediate values (the results of all subexpressions as well as variables) are pushed onto the stack until the end of the function. Simple compilers and virtual machines like HLVM and .NET on Windows Phone 7 actually work like this in practice even though this retains references for longer than necessary. With this model, each
new A() pushes a reference onto the stack until the function returns so all three are reachable from the stack at the point in question and, therefore, nothing is eligible for garbage collection.
Consider a model where references are removed from the stack at the first point where they are never read from again. This is closer to how production virtual machines like .NET and OCaml work except they keep local references in registers when possible and spill to pre-allocated entries in the function call's stack frame otherwise, overwriting dead locals to minimize the size of the stack frame. With this model, all references are dead at the point in question so none are reachable and, therefore, all three of the newly allocated objects are eligible for garbage collection as well as the
args array and all of the strings it references.
So we have not only shown that answers ranging from
everything can be justified but we have even cited real working virtual machines and garbage collectors that implement these models so our predictions are testable.
If I were given that question in an interview I would test the interviewer by explaining some of this. If they reacted well by expressing an interest in learning then I would still be interested in the job. If they reacted badly by trying to defend their ill-defined assumptions and untestable predictions then I would not want to work with them.