0

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.
    apply add_le_cases in H.
    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.
        rewrite <- add_assoc.
        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?

1 Answer 1

0

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 ++ s2is long enough, then length s2 >= pumping_constant re2, and you can apply IH2, then append s1to 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 s1is short.

1
  • 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

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.