# How to do induction on the length of a list in Coq?

When reasoning on paper, I often use arguments by induction on the length of some list. I want to formalized these arguments in Coq, but there doesn't seem to be any built in way to do induction on the length of a list.

How should I perform such an induction?

More concretely, I am trying to prove this theorem. On paper, I proved it by induction on the length of `w`. My goal is to formalize this proof in Coq.

• For concreteness, is there any particular property of lists that you would like to prove? Aug 25, 2017 at 0:41
• @arthur-azevedo-de-amorim Thank you for replying. It is an automat as here: ibb.co/nNUXe5 I want to prove some theorems about it. The coq code can be seen here: pastebin.ubuntu.com/25386445 I failed to continue. I manage to prove it by induction on list length in paper using informal langauge. Just don't know how to use coq to prove it. Aug 25, 2017 at 0:59

There are many general patterns of induction like this one that can be covered by the existing library on well founded induction. In this case, you can prove any property P by induction on length of lists by using `well_founded_induction`, `wf_inverse_image`, and `PeanoNat.Nat.lt_wf_0`, as in the following comand:

``````induction l using (well_founded_induction
(wf_inverse_image _ nat _ (@length _)
PeanoNat.Nat.lt_wf_0)).
``````

if you are working with lists of type `T` and proving a goal `P l`, this generates an hypothesis of the form

``````H : forall y : list T, length y < length l -> P y
``````

This will apply to any other datatype (like trees for instance) as long as you can map that other datatype to `nat` using any size function from that datatype to `nat` instead of `length`.

Note that you need to add `Require Import Wellfounded.` at the head of your development for this to work.

• Here is a slightly shorter variant `induction xs using (induction_ltof1 _ (@length _)); unfold ltof in *.`. But I'd prefer explicit naming: `induction xs as [xs IHxs] using (induction_ltof1 _ (@length _)); unfold ltof in IHxs.` Sep 27, 2017 at 7:57
• In case anyone is wondering, the necessary imports are: Require Import Coq.Arith.Wf_nat. Require Import Coq.Wellfounded.Wellfounded. Aug 6, 2018 at 20:56

Here is how to prove a general list-length induction principle.

``````Require Import List Omega.

Section list_length_ind.
Variable A : Type.
Variable P : list A -> Prop.

Hypothesis H : forall xs, (forall l, length l < length xs -> P l) -> P xs.

Theorem list_length_ind : forall xs, P xs.
Proof.
assert (forall xs l : list A, length l <= length xs -> P l) as H_ind.
{ induction xs; intros l Hlen; apply H; intros l0 H0.
- inversion Hlen. omega.
- apply IHxs. simpl in Hlen. omega.
}
intros xs.
apply H_ind with (xs := xs).
omega.
Qed.
End list_length_ind.
``````

You can use it like this

``````Theorem foo : forall l : list nat, ...
Proof.
induction l using list_length_ind.
...
``````

That said, your concrete example example does not necessarily need induction on the length. You just need a sufficiently general induction hypothesis.

``````Import ListNotations.

(* ... some definitions elided here ... *)

Definition flip_state (s : state) :=
match s with
| A => B
| B => A
end.

Definition delta (s : state) (n : input) : state :=
match n with
| zero => s
| one => flip_state s
end.

(* ...some more definitions elided here ...*)

Theorem automata221: forall (w : list input),
extend_delta A w = B <-> Nat.odd (one_num w) = true.
Proof.
assert (forall w s, extend_delta s w = if Nat.odd (one_num w) then flip_state s else s).
{ induction w as [|i w]; intros s; simpl.
- reflexivity.
- rewrite IHw.
destruct i; simpl.
+ reflexivity.
+ rewrite <- Nat.negb_even, Nat.odd_succ.
destruct (Nat.even (one_num w)), s; reflexivity.
}

intros w.
rewrite H; simpl.
destruct (Nat.odd (one_num w)); intuition congruence.
Qed.
``````

In case like this, it is often faster to generalize your lemma directly:

``````From mathcomp Require Import all_ssreflect.

Set Implicit Arguments.
Unset Strict Implicit.
Unset Printing Implicit Defensive.

Section SO.

Variable T : Type.
Implicit Types (s : seq T) (P : seq T -> Prop).

Lemma test P s : P s.
Proof.
move: {2}(size _) (leqnn (size s)) => ss; elim: ss s => [|ss ihss] s hs.
``````

Just introduce a fresh `nat` for the size of the list, and regular induction will work.