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