.. _sect-inductive: **************** Inductive Proofs **************** Before embarking on proving ``plus_commutes`` in Idris itself, let us consider the overall structure of a proof of some property of natural numbers. Recall that they are defined recursively, as follows: .. code-block:: idris data Nat : Type where Z : Nat S : Nat -> Nat A *total* function over natural numbers must both terminate, and cover all possible inputs. Idris checks functions for totality by checking that all inputs are covered, and that all recursive calls are on *structurally smaller* values (so recursion will always reach a base case). Recalling ``plus``: .. code-block:: idris plus : Nat -> Nat -> Nat plus Z m = m plus (S k) m = S (plus k m) This is total because it covers all possible inputs (the first argument can only be ``Z`` or ``S k`` for some ``k``, and the second argument ``m`` covers all possible ``Nat``) and in the recursive call, ``k`` is structurally smaller than ``S k`` so the first argument will always reach the base case ``Z`` in any sequence of recursive calls. In some sense, this resembles a mathematical proof by induction (and this is no coincidence!). For some property ``P`` of a natural number ``x``, we can show that ``P`` holds for all ``x`` if: - ``P`` holds for zero (the base case). - Assuming that ``P`` holds for ``k``, we can show ``P`` also holds for ``S k`` (the inductive step). In ``plus``, the property we are trying to show is somewhat trivial (for all natural numbers ``x``, there is a ``Nat`` which need not have any relation to ``x``). However, it still takes the form of a base case and an inductive step. In the base case, we show that there is a ``Nat`` arising from ``plus n m`` when ``n = Z``, and in the inductive step we show that there is a ``Nat`` arising when ``n = S k`` and we know we can get a ``Nat`` inductively from ``plus k m``. We could even write a function capturing all such inductive definitions: .. code-block:: idris nat_induction : (P : Nat -> Type) -> -- Property to show (P Z) -> -- Base case ((k : Nat) -> P k -> P (S k)) -> -- Inductive step (x : Nat) -> -- Show for all x P x nat_induction P p_Z p_S Z = p_Z nat_induction P p_Z p_S (S k) = p_S k (nat_induction P p_Z p_S k) Using ``nat_induction``, we can implement an equivalent inductive version of ``plus``: .. code-block:: idris plus_ind : Nat -> Nat -> Nat plus_ind n m = nat_induction (\x => Nat) m -- Base case, plus_ind Z m (\k, k_rec => S k_rec) -- Inductive step plus_ind (S k) m -- where k_rec = plus_ind k m n To prove that ``plus n m = plus m n`` for all natural numbers ``n`` and ``m``, we can also use induction. Either we can fix ``m`` and perform induction on ``n``, or vice versa. We can sketch an outline of a proof; performing induction on ``n``, we have: - Property ``P`` is ``\x => plus x m = plus m x``. - Show that ``P`` holds in the base case and inductive step: - | Base case: ``P Z``, i.e. | ``plus Z m = plus m Z``, which reduces to | ``m = plus m Z`` due to the definition of ``plus``. - | Inductive step: Inductively, we know that ``P k`` holds for a specific, fixed ``k``, i.e. | ``plus k m = plus m k`` (the induction hypothesis). Given this, show ``P (S k)``, i.e. | ``plus (S k) m = plus m (S k)``, which reduces to | ``S (plus k m) = plus m (S k)``. From the induction hypothesis, we can rewrite this to | ``S (plus m k) = plus m (S k)``. To complete the proof we therefore need to show that ``m = plus m Z`` for all natural numbers ``m``, and that ``S (plus m k) = plus m (S k)`` for all natural numbers ``m`` and ``k``. Each of these can also be proved by induction, this time on ``m``. We are now ready to embark on a proof of commutativity of ``plus`` formally in Idris.