Addition is Primitive Recursive

Theorem
The function $$\operatorname{add}: \N^2 \to \N$$, defined as:
 * $$\operatorname{add} \left({n, m}\right) = n + m$$

is primitive recursive‎.

Proof
We observe that:
 * $$\operatorname{add} \left({n, 0}\right) = n + 0 = n$$

and that
 * $$\operatorname{add} \left({n, m + 1}\right) = n + \left({m + 1}\right) = \left({n + m}\right) + 1 = \operatorname{succ} \left({\operatorname{add} \left({n, m}\right)}\right)$$

where $$\operatorname{succ}$$ is a basic primitive recursive‎ function.

We are to show that $$\operatorname{add}$$ is defined by primitive recursion.

So we need to find primitive recursive‎ functions $$f: \N \to \N$$ and $$g: \N^3 \to \N$$ such that:
 * $$\operatorname{add} \left({n, m}\right) = \begin{cases}

f \left({n}\right) & : m = 0 \\ g \left({n, m - 1, \operatorname{add} \left({n, m - 1}\right)}\right) & : m > 0 \end{cases}$$

Since $$\operatorname{add} \left({n, 0}\right) = n$$, we can see that $$f \left({n}\right) = n$$.

That is, $$f$$ is the basic primitive recursive‎ function $$\operatorname{pr}^1_1: \N \to \N$$.

Since $$\operatorname{add} \left({n, m + 1}\right) = \operatorname{succ} \left({\operatorname{add} \left({n, m}\right)}\right)$$, we can see that $$g$$ needs to be a function which maps the triple $$\left({n, m, \operatorname{add} \left({n, m}\right)}\right)$$ to $$\operatorname{succ} \left({\operatorname{add} \left({n, m}\right)}\right)$$.

A suitable function is:
 * $$g: \N^3 \to \N$$ where $$g \left({n_1, n_2, n_3}\right) = \operatorname{succ} \left({n_3}\right)$$

because then:
 * $$g \left({n, m, \operatorname{add} \left({n, m}\right)}\right) = \operatorname{succ} \left({\operatorname{add} \left({n, m}\right)}\right)$$.

Now we just need to show that $$g$$ is primitive recursive‎.

This is achieved by using the projection function:
 * $$g \left({n_1, n_2, n_3}\right) = \operatorname{succ} \left({\operatorname{pr}^3_3 \left({n_1, n_2, n_3}\right)}\right)$$.

Thus $$g$$ is obtained by substitution from the basic primitive recursive‎ functions $$\operatorname{succ}$$ and $$\operatorname{pr}^3_3$$ and so is primitive recursive‎.

So $$\operatorname{add}$$ is obtained by primitive recursion from the primitive recursive functions‎ $$\operatorname{pr}^1_1$$ and $$g$$, and so is primitive recursive‎.