# Proof that (prev n) <= m starting from n <= m

I have the next definition:

``````data Nat : Set where
zero : Nat
succ : Nat -> Nat

prev : Nat -> Nat
prev zero = zero
prev (succ n) = n

data _<=_ : Nat -> Nat -> Set where
z<=n : forall {n} -> zero <= n
s<=s : forall {n m} -> (n<=m : n <= m) -> (succ n) <= (succ m)
``````

It easy to proof the next lemma:

``````lem-prev : {x y : Nat} -> x <= y -> (prev x) <= (prev y)
lem-prev z<=n = z<=n
lem-prev (s<=s t) = t
``````

But I can't find a way to proof the next lemma:

``````lem-prev' : {x y : Nat} -> x <= y -> (prev x) <= y
``````

I can change definition of `<=` to the next:

``````data _<='_ : Nat -> Nat -> Set where
z<=n' : forall {n} -> zero <=' n
s<=s' : forall {n m} -> (n<=m : n <=' m) -> (succ n) <=' m
``````

In that case I can proof `lem-prev'`:

``````lem-prev' : {x y : Nat} -> x <=' y -> (prev x) <=' y
lem-prev' z<=n' = z<=n'
lem-prev' (s<=s' t) = t
``````

But now I can't proof `lem-prev`.

Is there a way to proof both lemmas for `<=` and/or `<='`? If no, then how should I change the definition to make it possible?

ADD: The solution using hammar's helper lemma:

``````lem-prev : {x y : Nat} -> x <= y -> (prev x) <= y
lem-prev z<=n = z<=n
lem-prev (s<=s prev-n<=prev-m) = weaken (prev-n<=prev-m)
``````
-
I don't agree with your suggested redefinition of `<=`, instead I think you have to start from `zero <= (succ n)`. –  Neil Oct 21 '12 at 0:02

Try this lemma:

``````weaken : {x y : Nat} -> x <= y -> x <= succ y
weaken z<=n = z<=n
weaken (s<=s n<=m) = s<=s (weaken n<=m)
``````
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argh! It took 3 hours for me to get the idea :) Thank you! –  Yuras Oct 21 '12 at 12:32