You're almost there, there's just one missing link in your understanding.
Local variables (or the references to the object stored in a local variable, if we're talking about non-primitive types) are actually stored in a local variable table, not on the operand stack. They're only pushed onto the stack when they are to be used by a call.
(What is confusing is that the local variable table itself is also stored on a stack, but that's a separate stack from what the bytecode uses for operands. From the bytecode's perspective it is a real table, with fixed size and freely indexable.)
You can use javap
to look at what bytecode is generated from your code. What you'll see is something like this:
public void test();
descriptor: ()V
flags: ACC_PUBLIC
Code:
stack=3, locals=3, args_size=1
0: new #2 // class Test$Bar
3: dup
4: invokespecial #3 // Method Test$Bar."<init>":()V
7: astore_1
8: new #4 // class Test$Foo
11: dup
12: invokespecial #5 // Method Test$Foo."<init>":()V
15: astore_2
16: getstatic #6 // Field java/lang/System.out:Ljava/io/PrintStream;
19: aload_1
20: invokevirtual #7 // Method java/io/PrintStream.println:(Ljava/lang/Object;)V
23: return
}
First of all, what is this line?
stack=3, locals=3, args_size=1
It is metadata that tells the JVM that this method has an operand stack no deeper than 3 entries, 3 local variables and takes 1 argument. But surely that isn't right, our method takes no argument and clearly only has 2 local variables!
The answer to this is that non-static methods always have a "0th argument": this
. This explains the argument count, and leads us to the next important discovery: arguments of a method are stored in the local variable table too. So our table will have entries 0,1,2, with 0 containing this
at the start and 1 and 2 uninitialised.
With that out of the way, let's look at the code! First up it's lines 0-7
:
- The
new
opcode creates a new instance of Bar
and stores the reference on the stack.
dup
creates a copy of the same reference on the top of the stack (so you've got two copies now sitting there)
invokespecial #3
calls the constructor of Bar
and consumes the top of the stack. (now we've only got one copy left)
astore_1
stores the remaining reference in local variable number number 1
(0
is for this
in this case)
This is what Object a = new Bar();
has been compiled into. Then you get the same for Object b = new Foo();
(lines 8-15
).
And then comes the interesting bit, from line 16
:
getstatic #6
pushes the value of System.out
on the stack
aload_1
pushes local variable number 1 (a
) on the stack too
invokevirtual #7
consumes both entries, calling println()
on System.out
with a
as its input parameter.
If you want to delve into it deeper, or you just want to point out my mistakes, the official reference for all of the above is here.