# On de Bruijn indices

In "Types and Programming Languages", section 6.1.2 they talk about a naming context used to number free variables in lambda expressions. Using the example scheme they've provided, both `λx.xb` and `λx.xx` will have their de Bruijn representation as `λ.00` when they're clearly different terms. How does this work?

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What makes you think the representation of the first one would be `λ.00`. I don't think the first can be represented at all since `b` isn't bound anywhere. –  sepp2k Feb 26 '12 at 4:06
In the section I mentioned, they talk about how free variables can be represented using a naming context. –  SCombinator Feb 26 '12 at 4:27
Ah, I see now. I'll write an answer shortly. –  sepp2k Feb 26 '12 at 4:42
As you mentioned the book uses a naming context which maps `n` free variables to the numbers from `0` to `n-1`. However if you look closely at the examples in the book, you'll notice that it doesn't use those numbers directly to represent the variables. For example it represents `λw. y w` as `λ. 4 0` even though the mapping for `y` is 3, not 4.
What's happening here is that he adds the nesting depth of the variable to the number. I.e. if a free variable `v` is nested in `d` lambdas, it gets the index `Γ(v)+d`, not just `Γ(v)`.
So in your example using the context `Γ {b -> 0}` `λx.xb` would be represented as `λ. 0 1`, not `λ. 0 0`. Thus there's no ambiguity.