There is a standard compiler setup, such as would be used for the C language, and then there is Java, which is significantly different.
The standard C compiler compiles (through several internal phases) into "machine instructions" which are directly understood by the x86 processor or whatever.
The Java compiler, on the other hand, compiles to what are sometimes called "bytecodes". These are machine instructions, but for an imaginary machine, the Java Virtual Machine. So the JVM interprets the bytecodes just like a "real" machine processes it's machine instructions. (The main advantage of this is that a program compiled into bytecodes will run on any JVM, whether it be on an x86 system, an IBM RISC box, or the ARM processor in a Android -- so long as there's a JVM the code will run.)
(There have historically been a number of "virtual machines" similar to Java, the UCSD Pascal "P-code" system being one of the more successful ones.)
But it gets more complicated --
Interpreting "bytecodes" is fairly slow and inefficient, so most Java implementations have some sort of scheme to translate the bytecodes into "real" machine instructions. In some cases this is done statically, in a separate compile step, but most often it's done with a "just-in-time compiler" (JITC) which converts small portions of the bytecodes to machine instructions while the application is running. These get to be quite elaborate, with complex schemes to decide which segments of code will benefit most from translating into hardware machine instructions. But they all, for the most part, do their magic without you needing to be aware of what's going on, and without you having to compile your Java code to target a specific type of processor.