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I recently found this theorem here, (at the bottom):

Any program can be transformed into a semantically equivalent program of one procedure containing one switch statement inside a while loop.

The Article went on to say :

A corollary to this theorem is that any program can be rewritten into a program consisting of a single recursive function containing only conditional statements

My questions are, are both these theorems applicable today ? Does similarly transforming a program reap any benefits ? I mean to say, is such a code optimized ? (Although recursion calls are slower, I know)

I read, from here, that switch-cases are almost always faster when optimized by the compiler. Does that make a difference. ?

PS: I'm trying to get some idea about compiler optimizations from here

And I've added the c tag as that's the only language I've seen optimized.

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The first article you cite is a little academic joke. Note that it says "a folk theorem" and not "a theorem". I would not try to learn anything about optimization from the first article. –  markgz Apr 25 '12 at 21:00
    
@markgz From wikipedia : folk theorem refers generally to any theorem that is believed and discussed, but has not been published. You're right : it is bit of a troll. But the conclusions seem to be true nevertheless. –  RaunakS Apr 25 '12 at 21:10
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3 Answers

up vote 6 down vote accepted

Its true. A Turing machine is essentially a switch statement on symbols that repeats forever, so its based pretty directly on Turing-machines-compute everything. A switch statement is just a bunch of conditionals, so you can clearly write such a program as a loop with just conditionals. Once you have that, making the loop from recursion is pretty easy although you may have to pass a lot of state variables as parameters if your language doesn't have true lexical scoping.

There's little reason to do any of this in practice. Such programs generally operate more slowly than the originals, and may take more space. So why would you possibly slow your program down, and/or make its load image bigger?

The only place this makes sense is if you intend to obfuscate the code. This kind of technique is often used as "control flow obfuscation".

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So, aside from obfuscation, such transforms serve no purpose at all. What if I use only switch and while, without using recursion at all ? Will there be a benefit ? –  RaunakS Apr 25 '12 at 21:14
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Generally, no. The only point of doing a semantics-preserving transformation is to a) optimize some aspect of the transformed program with respect to the original, [and the type of transformations being discussed generally pessimize time or space, or b) to enable some other transformation to take place that provides such an optimization. For an example of the latter, a complicated set of conditional reduced to a set of cases may all turn out to have the same case --> simpler switch --> possibly faster execution and definitely smaller code. ... –  Ira Baxter Apr 25 '12 at 21:19
    
... but there are other ways to determine such optimizations (e.g., common subexpression elimination, partial redundancy elimination) which tend to be useful in many cases, and these optimizations tend to already be built into compilers. –  Ira Baxter Apr 25 '12 at 21:20
    
Is such optimization done by the developer ? It would seem to be very involved. Or are they done automagically by the compiler ? –  RaunakS Apr 25 '12 at 21:22
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Common subexpression/Partial redundancy are involved and hard in general. They and many other optimizations are built into many compilers. Go read a standard compiler text (Aho and Ullman, "Compilers" is a classic) to get a better understanding of the kind of transformations built into compilers. –  Ira Baxter Apr 25 '12 at 21:23
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This is basically what happens when a compiler translates a program into machine code. The machine code runs on a processor, which executes instructions one-by-one in a loop. The complex structure of the program has become part of the data in memory.

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Recursive loops through a switch statement can be used to create a rudimentary virtual machine. If your virtual machine is Turing complete then, in theory, any program could be rewritten to work on this machine.

int opcode[] {
   PUSH,
   ADD
   ....
};

while (true) {
    switch (*opcode++) {
    case PUSH:
        *stack++ = <var>;
        break;
    case ADD:
        stack[-1] += stack[0];
        --stack;
        break;
     ....
    }
}

Of course writing a compiler for this virtual machine would be another matter. :-)

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Would this be how modern virtual machines are written ? (for instance, the JVM) –  RaunakS Apr 25 '12 at 21:19
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The vm I have illustrated is similar to how a language like Python would be interpreted. That is the vm is designed to interpret, or emulate, the bytecode of a different machine. These would be more optimised though (e.g. a table of function pointers may be faster than a switch statement). VMs that virtualise windows or similar use different technologies altogether involving CPU extensions and low-level hackery. –  Will Apr 25 '12 at 21:32
    
Fascinating. I never realized how much machinery is hidden behind the compiler veil (and we never seem to learns such matters in college). –  RaunakS Apr 25 '12 at 21:39
    
"We"? Most computer science curricula have compiler classes, or at least they used to. If you don't know how your programming language "works", you will likely not understand how to build big, reasonably efficient systems. –  Ira Baxter Apr 27 '12 at 20:46
    
@IraBaxter We don't, unfortunately. We do have one semester of automata ... but no compiler design. Our syllabi seem to be more focused on IT. –  RaunakS Apr 27 '12 at 22:32
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