# I have been stuck on MApp for pumping lemma

I have been trying to solve Pumping lemma in Coq.

I was on the third subgoal, `Mapp`.

``````Lemma pumping : forall T (re : reg_exp T) s,
s =~ re ->
pumping_constant re <= length s ->
exists s1 s2 s3,
s = s1 ++ s2 ++ s3 /\
s2 <> [] /\
length s1 + length s2 <= pumping_constant re /\
forall m, s1 ++ napp m s2 ++ s3 =~ re.
``````

My proof on `MApp` is as follow.

``````Proof.
intros T re s Hmatch.
induction Hmatch
as [ | x | s1 re1 s2 re2 Hmatch1 IH1 Hmatch2 IH2
| s1 re1 re2 Hmatch IH | re1 s2 re2 Hmatch IH
| re | s1 s2 re Hmatch1 IH1 Hmatch2 IH2 ].
- (* MEmpty -- omitted *)
- (* MChar -- omitted *)
- (* MApp *)
intros T re s Hmatch.
induction Hmatch
as [ | x | s1 re1 s2 re2 Hmatch1 IH1 Hmatch2 IH2
| s1 re1 re2 Hmatch IH | re1 s2 re2 Hmatch IH
| re | s1 s2 re Hmatch1 IH1 Hmatch2 IH2 ].
- (* MEmpty *)
simpl. intros contra. inversion contra.
- (* MChar *)
simpl. intros. inversion H. inversion H1.
- (* MApp *)
simpl. rewrite app_length. intros.
destruct H as [H|H].
+ (*case pumping_constant re1 <= length s1 ommitted*)
+ apply IH2 in H. destruct H as [ss1 [ss2 [ss3 [H1 [H2 [H3 H4]]]]]].
exists (s1++ss1), ss2, ss3. split.
* rewrite H1. rewrite <- app_assoc. reflexivity.
* split. apply H2.
split. rewrite app_length.
assert (Hc: length s1<pumping_constant re1 \/ length s1>=pumping_constant re1).
apply lt_ge_cases.
destruct Hc as [Hc|Hc].
apply le_S in Hc.
apply Sn_le_Sm__n_le_m in Hc.
apply (Plus.plus_le_compat _ _ _ _ Hc).
apply H3.
(* stuck *)
``````

I am now stuck on case `Hc: length s1>=pumping_constant re1`

``````Goal:
2 goals
T : Type
s1 : list T
re1 : reg_exp T
s2 : list T
re2 : reg_exp T
Hmatch1 : s1 =~ re1
Hmatch2 : s2 =~ re2
IH1 : pumping_constant re1 <= length s1 ->
exists s2 s3 s4 : list T,
s1 = s2 ++ s3 ++ s4 /\
s3 <> [ ] /\
length s2 + length s3 <= pumping_constant re1 /\
(forall m : nat, s2 ++ napp m s3 ++ s4 =~ re1)
IH2 : pumping_constant re2 <= length s2 ->
exists s1 s3 s4 : list T,
s2 = s1 ++ s3 ++ s4 /\
s3 <> [ ] /\
length s1 + length s3 <= pumping_constant re2 /\
(forall m : nat, s1 ++ napp m s3 ++ s4 =~ re2)
ss1, ss2, ss3 : list T
H1 : s2 = ss1 ++ ss2 ++ ss3
H2 : ss2 <> [ ]
H3 : length ss1 + length ss2 <= pumping_constant re2
H4 : forall m : nat, ss1 ++ napp m ss2 ++ ss3 =~ re2
Hc : length s1 >= pumping_constant re1
______________________________________(1/2)
length s1 + length ss1 + length ss2 <=
pumping_constant re1 + pumping_constant re2
``````

I tried solving it with cases `H: length s1>=pumping_constant -> re1 length s1=pumping_constant re1 \/ length s1>pumping_constatn re1`.

It got me somewhere but the right case is tough to crack. How should I proceed?

Intuitively (I didn't install the specific libraries), I would start with a case analysis on `length s1 >= pumping_constant re1`
• If it holds, you can apply IH1, then append `s2` to the right of the third component of the decomposition of `s1`.
• If `length s1 < pumping_constant re1` and `s1 ++ s2`is long enough, then `length s2 >= pumping_constant re2`, and you can apply `IH2`, then append `s1`to the left of the first component of the decomposition of `s2`.
In the sub-goal you display, I didn't find any hypothesis of the form `length s1 + length s2 >= pumping_constant re1 + pumping_constant re2`, which IMO helps to solve the case where `s1`is short.
• Thank you because you have give me inspiration. I should not destruct `length s1 + length s2 >= pumping_constant re1 + pumping_constant re2` instead I should do an analysis on `length s1>= pumping_constant re1 \/ length s1 < pumping_constant re1`. I have found my solution. Thank you again. Aug 1 at 3:05