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'
end
end.
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')
end.
```

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,
r>0->
included p h -> length p > length h*(r-1) -> exists x : A , count x p >r-1.
```

How to prove the lemmas?