# Idris proof with simplification causing "type mismatch" error

I am learning Idris by following along with this book: https://idris-hackers.github.io/software-foundations/pdf/sf-idris-2018.pdf

I kind of hit a snag when getting to the section on proof with simplification (yes it is right at the start). The small bit of code I am working on is:

``````namespace Numbers

data Nat : Type where
Zero : Numbers.Nat
Successor : Numbers.Nat -> Numbers.Nat

plus : Numbers.Nat -> Numbers.Nat -> Numbers.Nat
plus Zero b = b
plus (Successor a) b = Successor(plus a b)
``````

These simpler proofs work okay:

``````One : Numbers.Nat
One = Successor Zero

Two : Numbers.Nat
Two = Successor One

Three : Numbers.Nat
Three = Successor Two

proofOnePlusZero : plus One Zero = One
proofOnePlusZero = Refl

proofOnePlusZero' : plus Zero One = One
proofOnePlusZero' = Refl
``````

however as I tried to copy in the more complicated proof I get an error

``````-- works
plus_Z_n : (n : Numbers.Nat) -> plus Zero n = n
plus_Z_n n = Refl

-- breaks / errors
plus_Z_n' : (n : Numbers.Nat) -> plus n Zero = n
plus_Z_n' n = Refl
``````

This is the error

``````When checking right hand side of plus_Z_n' with expected type
plus n One = Successor n

Type mismatch between
Successor n = Successor n (Type of Refl)
and
plus n (Successor Zero) = Successor n (Expected type)

Specifically:
Type mismatch between
Successor n
and
plus n (Successor Zero)
``````

this is the expected behavior - however the recommendation is that one is able to understand why. I am at a loss and looking for hints or how to conisder this.

Here Idris just follows the definition (“proof of simplification”). So take `plus Zero n = n`. To simplify this type, the definition of `plus` helps: one branch defines `plus Zero b = b`. So we can replace `plus Zero n` with `n` to get to `n = n`, voilà. On the other hand, if trying to simplify `plus n Zero = n`, none of the branches in the definition of `plus` matches `plus n Zero`. So no replacement can be done and Idris is stuck with `plus n Zero = n`, until you help f.e. by case-splitting on `n`.

More precisely, if Idris tries to replace `plus x Zero`, it goes through all of the branches one by one and tries to match them, just as it would evaluate it. If it could be matched, it will stop. But only if the branch is equal to `plus x Zero`, it will be replaced. So given:

``````plus : Numbers.Nat -> Numbers.Nat -> Numbers.Nat
plus Zero b = b
plus a Zero = a
plus (Successor a) b = Successor(plus a b)

plus1 : plus n Zero = n
plus1 = Refl
``````

This won't compile, because `plus n Zero` could be handled by `plus Zero b = b`, depending on what `n` is. But because `n` is not known, Idris already stops here, but does not replace it. So the second branch is not reached.

• I think this was my inlcination following more consideration after originally posting. I am going to think about this some more to make sure I 100% get it. Before I get back to "accepting" here (since there is no code to try I want to make sure that it logically holds) Aug 15 '19 at 23:34
• Maybe defining `plus` with the recursion on the second argument helps understanding, `plus' a Z = a; plus' a (S b) = S (plus a b)`. Then `plus' n Zero = n` will be resolved, but `plus' Zero n = n` not so easily.
– xash
Aug 16 '19 at 8:10
• I think I get it. The remaining quesiton is if I add a third case to the definition of plus: `plus a Zero = a` the second proof still doesnt pass. I realize this is less than ideal coding style - but just trying to fully comprehend what is going on here. Wouldn't that be able to perform the replacement. Aug 16 '19 at 9:00
• Ah, good question. I edited the answer to extend on that bit.
– xash
Aug 16 '19 at 9:47
• Thank you - its official I get it (at least at some level). Aug 20 '19 at 17:29