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I am always curious as to why the JVM and CLR have a stack-based architecture? Why don't they use a register-based approach? What benefits does it have over the register-based approach?

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possible duplicate of Advanatges of stack-based architecture of the JVM's instruction –  Greg Hewgill Oct 28 '12 at 21:50
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It is usually not appropriate to just link out to an article but this time I'll make an exception: This article by Eric Lippert answers just this question.

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The blog post that usr linked to by Eric Lippert was one of many I've read that never really answers the ongoing debate about stack vs register. (Though Eric Lippert's a genius, so I would defer to him on most things, but I never saw him mention if he tried targeting a register VM with C#). He just shows a couple of trivial examples and then people debate it ad nauseum as usual. He wasn't writing a thesis. Like most blogs/articles of its type, (like this one), it gives a point of view based on the author's experience, then a guy from another camp shows up and argues against it. Then someone says something personal.

I used to ponder the differences between register and stack machines and compare instruction sequences, and run benchmarks...

Then I spent a couple of years implementing both types of machines: co-wrote the Parrot VM which was a register machine. We started, naively, with a fixed register set, in combination with data and register stacks, but realized it was an arbitrary limitation / hindrance, so we changed to an infinite register set and an allocator. At some point, the Parrot fast core (GCC computed goto) outperformed Mono and JVM when comparing pure VM opcode interpetation, but the difference came down to the JIT. Parrot's JIT never matched the quality of the others. It is the quality of the JITter that makes the eventual machine, and in most cases, that is what you compare. If all VMs played by the same rules (ie. they had a constraint to run in interpreted mode with no JIT), then my evidence shows a register machine has the performance edge on an equivalent stack machine. Larger instructions, but fewer of them (better IPC), and better cache locality of reference.

Very few VMs run opcodes exclusively (AFAIK), they JIT, and therein lies the performance. The point of the interpreter core is to establish a presence on the platform, and to provide a failsafe execution core in absence or failure of the JIT.

I remember working my tail off tweaking the core, testing and tuning, only to find that in the end we really wanted a fast JIT. So, I arrived at the conclusion that if you are going to JIT, it doesn't matter much whether you implement a stack or register machine to start, do what you like; but you will get "to market" faster with a stack machine. Doing a lot of pseudo-register-machine virtual optimizations for bytecode interpretation by a virtual machine core is at least partially a wasted effort, because it isn't true, native optimization. The soft-core doesn't do branch prediction, register renaming, instruction reordering, parallel execution or prefetch like a real processor. My feeling is that once we have a high quality JIT to native binary, we get to the same, rough eventual destination.

For that reason, I technically favor a stack based machine for:

  1. Simplicity - Much less code to maintain = less bugs
  2. Time to implement

But visually, and emotionally I favor a register machine for:

  1. Visual-Conceptual models more closely match the machine, and my brain
  2. Flexibility - Compilers can evaluate their expression trees in different orders using SSA.

Note I didn't say compilers could more "easily" generate code. That seems to be what people who have worked mostly with stack machines like to argue. I don't believe that and didn't find that the case. I saw a boatload of toy compilers written in a short time on both Parrot and the CLR, though I would admit the ones on the CLR are of higher quality, but I attribute that to the simple fact that the Parrot Foundation ain't Microsoft. Personally, I wrote toy compilers on both platforms myself, and found there are tradeoffs, but not enough to lose sleep over.

This is an educated guess, because my real-world experience does not include writing a full JITter so I didn't get first-hand experience comparing the pros and cons of JITting various forms of opcodes.

But my guess is, if you plan to include a JIT, then creating an extremely sophisticated virtual machine opcode core amounts to premature optimization, to me. A better use of your time is to use an intermediate / opcode form that will best serve the high level language compilers and JIT compiler, like an encoded AST or SSA form with type metadata, and spend more time on the quality of the JITter and the high level language(s) than tweaking the interpeter.

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