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I want to use the following lemmas to prove the strong form pigeon_hole principle.

Parameter A:Type.
Parameter  var_dec : forall (x y : A),{x=y}+{~x=y}. 

Definition included (l1 l2:list A):Prop :=
              forall x:A,In x l1 -> In x l2.

Fixpoint inbool (x:A) (l:list A) :bool :=
           match l with
           | nil => false
           | x'::l' => match (var_dec x' x) with
                           | left _ => true
                           | right _ => inbool x l'

Fixpoint diff(l1 l2:list A):nat :=
  match l2 with
  | nil => 0
  | x::l' => if inbool x l1 then diff l1 l' else S (diff (x::l1) l')

for example. diff [] {1,2} = 2; diff [] {1,2,2} = 2.

Lemma diff_le_length_le1:
  forall a l, diff (a::nil) l <= diff nil l.

Lemma include_diff:forall l1 l2,included l1 l2 -> diff nil l1 <= diff nil l2.

The strong form pigeon hole princible.

Theorem pigeon_hole_princible_sf:
            forall r:nat,forall h p,
             included p h -> length p > length h*(r-1) -> exists x : A , count x p >r-1.

How to prove the lemmas?

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Add more related tags, for quick response. –  laxonline Jan 22 '13 at 6:56
diff (x::[]) [] is equal to 0. –  lgbo Jan 22 '13 at 15:10
This is not a simple induction though. –  Ptival Jan 23 '13 at 23:32
In this example, if you start with diff nil l, during the execution of diff, there will be recursive calls where the first argument is not nil. This gives a hint that you should prove by induction statements where the first argument to the diff function should be an arbitrary variable, instead of nil. Try to find a more general statement than diff_le_length_le1, that is still always true, but where nil does not occur, and prove that one by induction. –  Yves Jan 24 '13 at 13:56

1 Answer 1

I've proven a generalization of the first lemma. You can find it here.

The most difficult part was simplifying objects out of the left side of diff. I needed to prove the following:

inbool a l1 = false -> inbool a l2 = false ->    diff (a :: l2) l1  = diff l2 l1
inbool a l1 = false -> inbool a l2 = true  ->    diff (a :: l2) l1  = diff l2 l1
inbool a l1 = true  -> inbool a l2 = false -> S (diff (a :: l2) l1) = diff l2 l1
inbool a l1 = true  -> inbool a l2 = true  ->    diff (a :: l2) l1  = diff l2 l1

It would probably easier to prove things about this other algorithm for diff.

Fixpoint diff (l1 l2 : list A) : nat :=
  match l2 with
  | nil => O
  | a :: l3 =>
    if inbool a l1
    then diff l1 l3
    else if inbool a l3
      then diff l1 l3
      else S (diff l1 l3)
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