# Proof - Coq - Do I need induction?

I have a scenario where I want to prove a lemma including a number of string and list variables. Probably, it needs 'induction', but can anybody help me proving the lemma given below. If the rest of code is needed, I can provide that too.

``````Definition DLVRI (IA IT : string)
(FA ICL FCL IUL FUL FTL : strlist) : bool :=
match (TestA IA FA),
(TestC ICL FCL),
(TestD IT IUL FUL FTL) with
| true, true, true => true
|  _  , _  , _    => false
end.

(**
Lemma TestDL : forall (IA IT : string),
forall (FA ICL FCL IUL FUL FTL : strlist),
(TestA IA FA) = true /\
(TestC ICL FCL) = true /\
(TestD IT IUL FUL FTL) = true.
Proof.
*)
(*  OR *)

Lemma TestDL : forall (IA IT : string),
forall (FA ICL FCL IUL FUL FTL : strlist),
(TestA IA FA) = true /\
(TestC ICL FCL) = true /\
(TestD IT IUL FUL FTL) = true
->   DLVRI IA IT FA ICL FCL IUL FUL FTL = true.
``````
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Here is a snippet that shows how to solve a similar goal.

``````Require Import String.

Parameter TestA: string -> list string -> bool.
Parameter TestC: list string -> list string -> bool.
Parameter TestD: string -> list string -> list string -> list string -> bool.

Definition DLVRI (IA IT : string)
(FA ICL FCL IUL FUL FTL : list string) : bool :=
match (TestA IA FA), (TestC ICL FCL), (TestD IT IUL FUL FTL) with
| true, true, true => true
|  _  , _  , _    => false
end.

Lemma TestDL:
forall
(IA IT : string)
(FA ICL FCL IUL FUL FTL : list string),
TestA IA FA = true ->
TestC ICL FCL = true ->
TestD IT IUL FUL FTL = true ->
DLVRI IA IT FA ICL FCL IUL FUL FTL = true.
Proof.
intros ???????? TA TC TD. unfold DLVRI. rewrite TA, TC, TD. reflexivity.
Qed.
``````

It is a really simple proof: just unfold the definition of DLVRI, and rewrite with hypotheses.

None that I replaced the hypothesis `(TestA IA FA) = true /\ (TestC ICL FCL) = true /\ (TestD IT IUL FUL FTL) = true` by three hypotheses. If you do not wish to do that, then the proof becomes:

``````intros ???????? HYP. destruct HYP as [TA [TC TD]]. unfold DLVRI. rewrite TA, TC, TD. reflexivity.
``````

However, it is probably better style to separate the hypotheses as I did, unless you usually manipulate such conjuctions. Otherwise, conjunctions get in the way of proofs and you always have to destruct/construct them.

EDIT: Since I didn't make it clear, you do not need induction for this proof. You would need to use induction if you stated a goal that needed to do recursive case analysis on the shape of a string list for instance.

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Its a great help. Thank you Robert. –  Khan Jun 18 '12 at 16:09