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I'm working through this Coq tutorial and I'm stuck with the one of the last exercises. I defined a datatype for the binary representation of natural numbers and now I want to convert natural numbers to this representation:

Inductive bin : Type :=
  | BO : bin
  | TO : bin -> bin
  | T1 : bin -> bin.

My first naive approach was this:

Fixpoint divmod_2 (n : nat) :=
  match n with
  | O => (O, 0)
  | S O => (O, 1)
  | S (S n') => match (divmod_2 n') with
                | (q, u') => ((S q), u')

Fixpoint to_bin (n : nat) : bin :=
  match n with
  | O => BO
  | S n' => match divmod_2 n' with
            | (q, 0) => TO (to_bin q)
            | (q, 1) => T1 (to_bin q)
            | (_, _) => BO

Coq stops at the definition of to_bin saying:

Recursive definition of to_bin is ill-formed.
In environment
to_bin : nat -> bin
n : nat
n' : nat
q : nat
n0 : nat
Recursive call to to_bin has principal argument equal to "q" instead of

So here's the question: How do I fix this to_bin function ?
Do I have to provide a proof for well founded recursion as described here ?
I assume that there is a simpler solution since it's a newbie tutorial ?

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1 Answer 1

up vote 3 down vote accepted

I think the easiest solution would be to define a successor function for binary naturals first, and then to use it to convert the successor of unary naturals.

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That is the proper way to do it. Just recur normally to compute to_bin n', and now you just need to add one to that bin number, which you can do easily by writing a succ : bin -> bin and simple pattern-matching. As Exercise 5 points out, the other modes of recursion are for later in the book. –  Ptival Feb 22 '13 at 0:11
I concur, you write to write a function nat -> bin so your "thinking" should consider the two questions 1/ what is the value of my function on 0; 2/ if I already know the value on p, what will be the value on (S p). So, you follow the structure of the input. Your thinking follows the structure of the output, which why you get stuck. –  Yves Feb 25 '13 at 21:55

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