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I am in the middle of coding up a compiler for a C like language.

I have gotten past syntax and semantic checking and I am beginning the code generation phase.

The final code that I have to generate has to be in 3 address load/store architecture. I'm allowed to assume an unbounded set of registers and a 32 M memory space for stack and system memory.

Right now, when I start generating the code, I begin by assuming a really large int array int R[2000000] to denote the register set. And as and when I encounter a variable declaration (through the parser/semantic analyzer) I allocate a register for that particular variable.

Now in the course of the program when I encounter this variable again, I retrieve it back from that register number. I save the register number of every variable in the symbol table.

My question now is this: Suppose, we have a statement like this -

a := b + c + e / f *h;

And I have saved a,b,c,e,f,h in R1, R2, R3, R4, R5, R6 respectively, the final generated code would be (assuming that the next available regs start from R7...)

R9 = R5 * R6;
R8 = R4 / R9;
R7 = R3 + R8;
R1 = R2 + R7;

What is the approach to "remember" what was the previous register and the operation?

If this is not the correct way of doing it, can anyone please give me some pointers on how to implement it?

Any suggestion would be great. Thanks

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3 Answers 3

I suggest you may simply enumerate operations and use it number as number of register which hold result value. If you use tree representation, then register numbers on which operation performed is numbers of child nodes. Also, you can use stack machine for intermediate code representation.

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Assuming an unbound register set feels like "cheating". In that case, I guess that you could go right ahead and pick the next available register, as you go along.

In a real-world situation, register assignment is typically done using "graph coloring". In the simple case, a graph consists of nodes representing variables (including temporary values) and arcs representing conflicts between variables. The goal is to assign each variable with a color (representing a register number) so that no two conflicting registers have the same color. (Historically, this problem is similar to the problem of drawing a map of the countries in the world, hence the use of the term "color".)

If the algorithm fail to find a suitable coloring, you have to "spill" some variables, e.g. place them on the stack.

Register allocation can be done either before or after code generation, each will give rise to different interesting problems.

Other things that you might need to consider is calling-convention, where the parameters and return values of a function must be placed in specific registers.

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In fact it is ok to assume an infinite number of registers (btw., why numbering them? Naming works better). And in the next pass you can translate this 3-address code into an SSA form, which makes an efficient register allocation much simpler than the classic graph coloring heuristics. This is exactly what LLVM does. – SK-logic Feb 26 '11 at 12:59

Such expression are often represented with a tree. Each node correspond to an operation, and each node contains the index of the register that holds the result.

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