# Will this 'algorithm' for nullable and first work (in a parser)?

Working through this for fun: http://www.diku.dk/hjemmesider/ansatte/torbenm/Basics/

Example calculation of nullable and first uses a fixed-point calculation. (see section 3.8)

I'm doing things in Scheme and relying a lot on recursion.

If you try to implement nullable or first via recursion, it should be clear you'll recur infinitely on a production like

`N -> N a b`

where N is a non-terminal and a,b are terminals.

Could this be solved, recursively, by maintaining a set of non-terminals seen on the left hand side of production rules, and ignoring them after we have accounted for them once?

This seems to work for nullable. What about for first?

EDIT: This is what I have learned from playing around. Source code link at bottom.

Non terminals cannot be ignored in the calculation of first unless they are nullable.

Consider:

``````N -> N a
N -> X
N ->
``````

Here we can ignore `N` in `N a` because `N` is nullable. We can replace `N -> N a` with `N -> a` and deduce that `a` is a member of `first(N)`.

Here we cannot ignore `N`:

``````N -> N a
N -> M
M -> b
``````

If we ignored the `N` in `N -> N a` we would deduce that `a` is in `first(N)` which is false. Instead, we see that N is not nullable, and hence when calculating first, we can omit any production where `N` is found as the first symbol in the RHS.

This yields:

``````N -> M
M -> b
``````

which tells us `b` is in `first(N)`.

Source Code: http://gist.github.com/287069

So ... does this sound OK?

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You not only have an infinite recursion program, but even on a computer with infinite compute capacity, you haven't provided any way to terminate this production - what other values can N have that don't include N? –  Alex Brown Jan 26 '10 at 16:28
Sorry, that was just one sample rule to illustrate my point. I'll try to fill out the question on my lunch break, and show some code, sample data, etc. –  z5h Jan 26 '10 at 16:30

I suggest to keep on reading :)

`3.13 Rewriting a grammar for LL(1) parsing` and especially `3.13.1 Eliminating left-recursion`.

Just to note you can run into indirect left recursion as well:

``````A -> Bac
B -> A
B -> _also something else_
``````

But the solution here is quite similar to eliminating the direct left recursion as in your first example.

You might want to check this paper which explains it in a little bit more straight-forward way. Less theory :)

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