I'm trying to prove the following in Coq:
∀ B: Type, ∀ a: B, ∀ b: nat -> B -> B, ∃ f: nat -> B, f 0 = a ∧ ∀ n: nat, f (S n) = b n (f n).
Which implies that a fairly general class of recursive functions exist. I know that I can construct that function using Fixpoint items or fix expressions, but I want to not use it, and instead use nat_ind defined with this type:
∀ P: nat → Prop, P 0 → (∀ n: nat, P n → P (S n)) → ∀ n: nat, P n
I believe this is possible since nat_ind behaves like a recursion combinator. But I didn't figured it out how to prove it. The problem is that the induction variable is inside of ∃ f guard, and I don't have access to it. I'm able to prove something like this:
∀ B: Type, ∀ a: B, ∀ b: nat -> B -> B, ∀ m: nat,
∃ f: nat -> B, f 0 = a ∧ ∀ n: nat, n < m -> f (S n) = b n (f n)
But it doesn't help in proving the original one I think.
Is it possible to prove the original one without using fix directly? I'm ok with using double negation and other well-known axioms if needed. Using nat_rec and nat_rect is also fine, but only as an opaque axiom. Precisely, using those are fine:
Axiom nat_rec2: ∀ P : nat → Set, P 0 → (∀ n : nat, P n → P (S n)) → ∀ n : nat, P n.
Axiom nat_rect2: ∀ P : nat → Type, P 0 → (∀ n : nat, P n → P (S n)) → ∀ n : nat, P n.
The problem seems to be to obtain recursion from the following axiomatization of nat:
Parameter nat : Type.
Parameter O : nat.
Parameter S : nat -> nat.
Parameter disjoint_O_S : forall n, O <> S n.
Parameter injective_S : forall n n', S n = S n' -> n = n'.
Parameter nat_rect : forall P: nat -> Type, P O -> (forall n: nat, P n -> P (S n)) -> forall n : nat, P n.
Where the main issue is that the nat_rect axiom has no computational behavior, so although we might define a recursor B -> (nat -> B -> B) -> nat -> B as nat_rect (fun _ => B), we can't prove anything about it.
The solution is to first encode the graph of the desired recursive function f as a relation, and then use nat_rect to produce a dependent pair, of a value that is going to be f n with evidence that that value is in the graph of f.
Section Rec.
Context (B : Type) (a : B) (b : nat -> B -> B).
Inductive graph : nat -> B -> Prop :=
| recO : graph O a
| recS n y : graph n y -> graph (S n) (b n y)
.
Lemma graph_fun : forall n, { y | forall y', y = y' <-> graph n y' }.
Proof.
induction n as [ | n IH ] using nat_rect.
- exists a; split.
+ intros <-. constructor.
+ inversion 1; [ reflexivity | ]. contradiction (disjoint_O_S n); auto.
- destruct IH as [y IH]. exists (b n y); split.
+ intros <-. constructor. apply IH. auto.
+ inversion 1; subst. contradiction (disjoint_O_S n); auto.
apply injective_S in H0. subst.
apply IH in H1. subst; auto.
Qed.
Theorem nat_rec : exists (f : nat -> B), f O = a /\ forall n, f (S n) = b n (f n).
Proof.
exists (fun n => proj1_sig (graph_fun n)). split.
- apply (proj2_sig (graph_fun O)). constructor.
- intros n. apply (proj2_sig (graph_fun (S n))).
constructor. apply (proj2_sig (graph_fun n)).
reflexivity.
Qed.
End Rec.
If you have the Prop inductor nat_ind instead of nat_rect, that same technique can be adapted by also assuming the axiom constructive_indefinite_description (which actually lets you reconstruct nat_rect, but here you can more simply apply it at the beginning of graph_fun):
From Coq Require Import IndefiniteDescription.
About constructive_indefinite_description.
(*
constructive_indefinite_description :
forall (A : Type) (P : A->Prop),
(exists x, P x) -> { x : A | P x }.
*)
My code:
law : ∀ a x → ((suc a) * (suc a) ÷ (suc a) ⟨ x ⟩) →ℕ ≡ (suc a , refl)
law a x = refl
I think there's too many suc a and I want to give an alias to suc a, something like (this code just describes my idea, it doesn't compile):
law : ∀ a x → ((s : suc a) * s ÷ s ⟨ x ⟩) →ℕ ≡ (s , refl)
law a x = refl
Can I achieve that?
Sure. You can use let
law : ∀ a x → let s = suc a in (s * s ÷ s ⟨ x ⟩) →ℕ ≡ (s , refl)
law a x = refl
or define an anonymous module:
module _ (a : ℕ) where
s = suc a
law : ∀ x → (s * s ÷ s ⟨ x ⟩) →ℕ ≡ (s , refl)
law x = refl
Outside of the module law has the same type signature as the one you provided.
I am pretty new to Agda. I am working on a question from the assignment. I have got most of it but there is one goal on which i am stuck.
data Arith : Set where
Num : ℕ → Arith
Plus : Arith → Arith → Arith
Times : Arith → Arith → Arith
eval : Arith → ℕ
eval (Num x) = x
eval (Plus e1 e2) = eval e1 + eval e2
eval (Times e1 e2) = eval e1 * eval e2
data Even : ℕ → Set where
zEven : Even 0
ssEven : {n : ℕ} → Even n → Even (suc (suc n))
-- [PROBLEM 1]
plusEven : ∀ n m → Even n → Even m → Even (n + m)
plusEven zero m x x₁ = x₁
plusEven (suc zero) m () x₁
plusEven (suc (suc .0)) m (ssEven zEven) x₁ = ssEven x₁
plusEven (suc (suc ._)) m (ssEven (ssEven x)) x₁ = ssEven (ssEven (plusEven _ m x x₁ ))
-- [PROBLEM 2]
timesEven : ∀ n m → Even n → Even m → Even (n * m)
timesEven zero m x x₁ = zEven
timesEven (suc ._) zero (ssEven x) x₁ = (timesEven _ zero x x₁)
timesEven (suc ._) (suc ._) (ssEven x) (ssEven x₁) = ssEven ((λ h → {!!}) (timesEven _ _ x x₁))
The goal I have to prove is
Goal: Even (.n₁ + suc (suc (.n₁ + .n * suc (suc .n₁))))
I feel that I have to use plusEven some how. But the goal does not look that straightforward. Have I made the problem difficult for me? or am I on the right track? Is there an easier way to do this? I don't want the solution to this. But a push in the right direction would be appreciated. I have been stuck on this for a while now.
If n is even, then n * m is even too, so it's irrelevant whether m is even or not and hence you should just throw away this constraint. So the actual theorems are (I made n and m implicit, because this is convenient)
timesEvenLeft : ∀ {n m} → Even n → Even (n * m)
timesEvenRight : ∀ {n m} → Even m → Even (n * m)
You can prove that n * m ≡ m * n and derive the latter theorem from the former. Hence it only remains to prove the first one. In the recursive case you need to prove Even (suc (suc n) * m) (which reduces to Even (m + (m + n * m)) having Even (n * m) (the induction hypothesis) in scope. For this you'll need yet another lemma:
plusDoubleEven : ∀ {n} m → Even n → Even (m + (m + n))
I really liked the answers posted here and they helped me a lot. But I cannot change the question given in the assignment. I used the answers posted to come up with a solution to the problem. It took me a while and it looks a little messy but it works. Thought i'd post it here too.
timesEven : ∀ n m → Even n → Even m → Even (n * m)
timesEven zero m x x₁ = zEven
timesEven (suc zero) m () x₁
timesEven (suc (suc n)) zero (ssEven x) x₁ = timesEven n zero x x₁
timesEven (suc (suc n)) (suc zero) x ()
timesEven (suc (suc n)) (suc (suc m)) (ssEven x) (ssEven x₁) = ssEven ((λ h → plusEven m (suc (suc (m + n * suc (suc m)))) x₁ (ssEven (plusEven m (n * suc (suc m)) x₁ h))) (timesEven n (suc (suc m)) x (ssEven x₁)))
It's probably not what is expected of you for this homework but a clean way to deal with these lemmas without doing too much work is, as hinted at by #user3237465, to reuse well-known properties of the natural numbers.
One way to get more out of these well-known properties is to introduce an alternative definition of Even which you can prove equivalent to the inductive one:
data Even : ℕ → Set where
zEven : Even 0
ssEven : {n : ℕ} → Even n → Even (suc (suc n))
record Even′ (n : ℕ) : Set where
constructor mkEven′
field factor : ℕ
.equality : n ≡ factor * 2
open Even′
Even⇒Even′ : {n : ℕ} → Even n → Even′ n
(...)
Even′⇒Even : {n : ℕ} → Even′ n → Even n
(...)
You can then prove plusEven and timesEven(Right/Left) by using equational reasoning, reusing lemmas from the standard library. For instance the proof of plusEven becomes:
plusEven′ : ∀ n m → Even′ n → Even′ m → Even′ (n + m)
plusEven′ n m (mkEven′ p Hp) (mkEven′ q Hq) = mkEven′ (p + q) eq where
.eq : n + m ≡ (p + q) * 2
eq = begin
n + m ≡⟨ cong₂ _+_ Hp Hq ⟩
p * 2 + q * 2 ≡⟨ sym (distribʳ-*-+ 2 p q) ⟩
(p + q) * 2
∎
plusEven : ∀ n m → Even n → Even m → Even (n + m)
plusEven n m en em = Even′⇒Even (plusEven′ n m (Even⇒Even′ en) (Even⇒Even′ em))
Here is a gist with all the right imports and all the proofs.
I want to write proofs of the statement "for all x there exist a y such that x < y and y is even ".
I tried in this way...
-- ll means less function i.e ' < '
_ll_ : ℕ → ℕ → Bool
0 ll 0 = false
0 ll _ = true
a ll 0 = false
(suc a) ll (suc b) = a ll b
even : ℕ → Bool
even 0 = true
even 1 = false
even (suc (suc n)) = even n
Teven : Bool → Set
Teven true = ⊤
Teven false = ⊥
thm0 : (x : ℕ) → Σ[ y ∈ ℕ ] (Teven ( and (x ll y) (even y)))
thm0 0 = suc (suc zero) , record {}
thm0 (suc a) = ?
for the last line i.e for 'suc a' agda is not able to find solution. I once tried by writing 2 * suc a , record {}. But this is also not working. Any help will be appreciated.
What you actually want is to do two steps at once.
The problem with this kind of definitions is something that is called "boolean blindness" - by encoding your propositions as booleans, you lose any kind of useful information they contain. The effect is that you have to rely on normalization to (hopefully) do its thing, you cannot help Agda in any other way (say by pattern matching on proof terms).
However, in your case, you can change the definition of thm0 slightly to help Agda with normalization. even makes two suc steps in every recursion step - you can make thm0 do two steps as well.
Let's take a look:
thm0 : ∀ x → ∃ λ y → Teven ((x ll y) ∧ (even y))
thm0 zero = suc (suc zero) , tt
Two new cases are for suc zero (also known as 1):
thm0 (suc zero) = suc (suc zero) , tt
And for suc (suc x'):
thm0 (suc (suc x') = ?
Now, if we knew that y (the one you existentially quantified over) is suc (suc y') for some other y', Agda could normalize even y to even y' (this is just following the definition). Same deal with the "less-than" proof - once you know that x = suc (suc x') and y = suc (suc y') for some y' (x' we already know), you can reduce x ll y to x' ll y'.
So the choice for y is simple... but how do we get y' (and the proof, of course)? We can use induction (recursion) and apply thm0 to x'! Remember that given x', thm0 returns some y' together with a proof that even y' and x' ll y' - this is precisely what we need.
thm0 (suc (suc a)) with thm0 a
... | y' , p = ?
Then we simply plug in y = suc (suc y') and p (as stated above, (x ll y) ∧ even y reduces to (x' ll y') ∧ even y', which is p).
Final code:
thm0 : ∀ x → ∃ λ y → Teven ((x ll y) ∧ (even y))
thm0 zero = suc (suc zero) , tt
thm0 (suc zero) = suc (suc zero) , tt
thm0 (suc (suc x')) with thm0 x'
... | y' , p = suc (suc y') , p
However, that being said, I'd advice against this. Do not encode your propositions as booleans and then use them at the type level via Teven. This really only works for simple things and cannot be extended to more complicated propositions. Instead, try explicit proof terms:
data _less-than_ : ℕ → ℕ → Set where
suc : ∀ {x y} → x less-than y → x less-than suc y
ref : ∀ {x} → x less-than suc x
data Even : ℕ → Set where
zero : Even 0
suc-suc : ∀ {x} → Even x → Even (2 + x)
thm0 can be then written using a simple lemma:
something-even : ∀ n → Even n ⊎ Even (suc n)
something-even zero = inj₁ zero
something-even (suc n) with something-even n
... | inj₁ x = inj₂ (suc-suc x)
... | inj₂ y = inj₁ y
(this states that either n is even or its successor is even). In fact, thm0 can be implemented without using recursion!
thm0 : ∀ x → ∃ λ y → Even y × x less-than y
thm0 n with something-even n
... | inj₁ x = suc (suc n) , suc-suc x , suc ref
... | inj₂ y = suc n , y , ref
Funnily enough, when I wrote this definition, I just pattern matched on something-even (suc n) and used C-a (autocomplete) to fill in the right sides! When given enough hints, Agda can write the code without my help.
Suppose we define a function
f : N \to N
f 0 = 0
f (s n) = f (n/2) -- this / operator is implemented as floored division.
Agda will paint f in salmon because it cannot tell if n/2 is smaller than n. I don't know how to tell Agda's termination checker anything. I see in the standard library they have a floored division by 2 and a proof that n/2 < n. However, I still fail to see how to get the termination checker to realize that recursion has been made on a smaller subproblem.
Agda's termination checker only checks for structural recursion (i.e. calls that happen on structurally smaller arguments) and there's no way to establish that certain relation (such as _<_) implies that one of the arguments is structurally smaller.
Digression: Similar problem happens with positivity checker. Consider the standard fix-point data type:
data μ_ (F : Set → Set) : Set where
fix : F (μ F) → μ F
Agda rejects this because F may not be positive in its first argument. But we cannot restrict μ to only take positive type functions, or show that some particular type function is positive.
How do we normally show that a recursive functions terminates? For natural numbers, this is the fact that if the recursive call happens on strictly smaller number, we eventually have to reach zero and the recursion stops; for lists the same holds for its length; for sets we could use the strict subset relation; and so on. Notice that "strictly smaller number" doesn't work for integers.
The property that all these relations share is called well-foundedness. Informally speaking, a relation is well-founded if it doesn't have any infinite descending chains. For example, < on natural numbers is well founded, because for any number n:
n > n - 1 > ... > 2 > 1 > 0
That is, the length of such chain is limited by n + 1.
≤ on natural numbers, however, is not well-founded:
n ≥ n ≥ ... ≥ n ≥ ...
And neither is < on integers:
n > n - 1 > ... > 1 > 0 > -1 > ...
Does this help us? It turns out we can encode what it means for a relation to be well-founded in Agda and then use it to implement your function.
For simplicity, I'm going to bake the _<_ relation into the data type. First of all, we must define what it means for a number to be accessible: n is accessible if all m such that m < n are also accessible. This of course stops at n = 0, because there are no m so that m < 0 and this statement holds trivially.
data Acc (n : ℕ) : Set where
acc : (∀ m → m < n → Acc m) → Acc n
Now, if we can show that all natural numbers are accessible, then we showed that < is well-founded. Why is that so? There must be a finite number of the acc constructors (i.e. no infinite descending chain) because Agda won't let us write infinite recursion. Now, it might seem as if we just pushed the problem back one step further, but writing the well-foundedness proof is actually structurally recursive!
So, with that in mind, here's the definition of < being well-founded:
WF : Set
WF = ∀ n → Acc n
And the well-foundedness proof:
<-wf : WF
<-wf n = acc (go n)
where
go : ∀ n m → m < n → Acc m
go zero m ()
go (suc n) zero _ = acc λ _ ()
go (suc n) (suc m) (s≤s m<n) = acc λ o o<sm → go n o (trans o<sm m<n)
Notice that go is nicely structurally recursive. trans can be imported like this:
open import Data.Nat
open import Relation.Binary
open DecTotalOrder decTotalOrder
using (trans)
Next, we need a proof that ⌊ n /2⌋ ≤ n:
/2-less : ∀ n → ⌊ n /2⌋ ≤ n
/2-less zero = z≤n
/2-less (suc zero) = z≤n
/2-less (suc (suc n)) = s≤s (trans (/2-less n) (right _))
where
right : ∀ n → n ≤ suc n
right zero = z≤n
right (suc n) = s≤s (right n)
And finally, we can write your f function. Notice how it suddenly becomes structurally recursive thanks to Acc: the recursive calls happen on arguments with one acc constructor peeled off.
f : ℕ → ℕ
f n = go _ (<-wf n)
where
go : ∀ n → Acc n → ℕ
go zero _ = 0
go (suc n) (acc a) = go ⌊ n /2⌋ (a _ (s≤s (/2-less _)))
Now, having to work directly with Acc isn't very nice. And that's where Dominique's answer comes in. All this stuff I've written here has already been done in the standard library. It is more general (the Acc data type is actually parametrized over the relation) and it allows you to just use <-rec without having to worry about Acc.
Taking a more closer look, we are actually pretty close to the generic solution. Let's see what we get when we parametrize over the relation. For simplicity I'm not dealing with universe polymorphism.
A relation on A is just a function taking two As and returning Set (we could call it binary predicate):
Rel : Set → Set₁
Rel A = A → A → Set
We can easily generalize Acc by changing the hardcoded _<_ : ℕ → ℕ → Set to an arbitrary relation over some type A:
data Acc {A} (_<_ : Rel A) (x : A) : Set where
acc : (∀ y → y < x → Acc _<_ y) → Acc _<_ x
The definition of well-foundedness changes accordingly:
WellFounded : ∀ {A} → Rel A → Set
WellFounded _<_ = ∀ x → Acc _<_ x
Now, since Acc is an inductive data type like any other, we should be able to write its eliminator. For inductive types, this is a fold (much like foldr is eliminator for lists) - we tell the eliminator what to do with each constructor case and the eliminator applies this to the whole structure.
In this case, we'll do just fine with the simple variant:
foldAccSimple : ∀ {A} {_<_ : Rel A} {R : Set} →
(∀ x → (∀ y → y < x → R) → R) →
∀ z → Acc _<_ z → R
foldAccSimple {R = R} acc′ = go
where
go : ∀ z → Acc _ z → R
go z (acc a) = acc′ z λ y y<z → go y (a y y<z)
If we know that _<_ is well-founded, we can skip the Acc _<_ z argument completly, so let's write small convenience wrapper:
recSimple : ∀ {A} {_<_ : Rel A} → WellFounded _<_ → {R : Set} →
(∀ x → (∀ y → y < x → R) → R) →
A → R
recSimple wf acc′ z = foldAccSimple acc′ z (wf z)
And finally:
<-wf : WellFounded _<_
<-wf = {- same definition -}
<-rec = recSimple <-wf
f : ℕ → ℕ
f = <-rec go
where
go : ∀ n → (∀ m → m < n → ℕ) → ℕ
go zero _ = 0
go (suc n) r = r ⌊ n /2⌋ (s≤s (/2-less _))
And indeed, this looks (and works) almost like the one in the standard library!
Here's the fully dependent version in case you are wondering:
foldAcc : ∀ {A} {_<_ : Rel A} (P : A → Set) →
(∀ x → (∀ y → y < x → P y) → P x) →
∀ z → Acc _<_ z → P z
foldAcc P acc′ = go
where
go : ∀ z → Acc _ z → P z
go _ (acc a) = acc′ _ λ _ y<z → go _ (a _ y<z)
rec : ∀ {A} {_<_ : Rel A} → WellFounded _<_ →
(P : A → Set) → (∀ x → (∀ y → y < x → P y) → P x) →
∀ z → P z
rec wf P acc′ z = foldAcc P acc′ _ (wf z)
I would like to offer a slightly different answer than the ones given above. In particular, I want to suggest that instead of trying to somehow convince the termination checker that actually, no, this recursion is perfectly fine, we should instead try to reify the well-founded-ness so that the recursion is manifestly fine in virtue of being structural.
The idea here is that the problem comes from being unable to see that n / 2 is somehow a "part" of n. Structural recursion wants to break a thing into its immediate parts, but the way that n / 2 is a "part" of n is that we drop every other suc. But it's not obvious up front how many to drop, we have to look around and try to line things up. What would be nice is if we had some type that had constructors for "multiple" sucs.
To make the problem slightly more interesting, let's instead try to define the function that behaves like
f : ℕ → ℕ
f 0 = 0
f (suc n) = 1 + (f (n / 2))
that is to say, it should be the case that
f n = ⌈ log₂ (n + 1) ⌉
Now naturally the above definition won't work, for the same reasons your f won't. But let's pretend that it did, and let's explore the "path", so to speak, that the argument would take through the natural numbers. Suppose we look at n = 8:
f 8 = 1 + f 4 = 1 + 1 + f 2 = 1 + 1 + 1 + f 1 = 1 + 1 + 1 + 1 + f 0 = 1 + 1 + 1 + 1 + 0 = 4
so the "path" is 8 -> 4 -> 2 -> 1 -> 0. What about, say, 11?
f 11 = 1 + f 5 = 1 + 1 + f 2 = ... = 4
so the "path" is 11 -> 5 -> 2 -> 1 -> 0.
Well naturally what's going on here is that at each step we're either dividing by 2, or subtracting one and dividing by 2. Every naturally number greater than 0 can be decomposed uniquely in this fashion. If it's even, divide by two and proceed, if it's odd, subtract one and divide by two and proceed.
So now we can see exactly what our data type should look like. We need a type that has a constructor that means "twice as many suc's" and another that means "twice as many suc's plus one", as well as of course a constructor that means "zero sucs":
data Decomp : ℕ → Set where
zero : Decomp zero
2*_ : ∀ {n} → Decomp n → Decomp (n * 2)
2*_+1 : ∀ {n} → Decomp n → Decomp (suc (n * 2))
We can now define the function that decomposes a natural number into the Decomp that corresponds to it:
decomp : (n : ℕ) → Decomp n
decomp zero = zero
decomp (suc n) = decomp n +1
It helps to define +1 for Decomps:
_+1 : {n : ℕ} → Decomp n → Decomp (suc n)
zero +1 = 2* zero +1
(2* d) +1 = 2* d +1
(2* d +1) +1 = 2* (d +1)
Given a Decomp, we can flatten it down into a natural number that ignores the distinctions between 2*_ and 2*_+1:
flatten : {n : ℕ} → Decomp n → ℕ
flatten zero = zero
flatten (2* p) = suc (flatten p)
flatten (2* p +1 = suc (flatten p)
And now it's trivial to define f:
f : ℕ → ℕ
f n = flatten (decomp n)
This happily passes the termination checker with no trouble, because we're never actually recursing on the problematic n / 2. Instead, we convert the number into a format that directly represents its path through the number space in a structurally recursive way.
Edit It occurred to me only a little while ago that Decomp is a little-endian representation of binary numbers. 2*_ is "append 0 to the end/shift left 1 bit" and 2*_+1 is "append 1 to the end/shift left 1 bit and add one". So the above code is really about showing that binary numbers are structurally recursive wrt dividing by 2, which they ought to be! That makes it much easier to understand, I think, but I don't want to change what I wrote already, so we could instead do some renaming here: Decomp ~> Binary, 2*_ ~> _,zero, 2*_+1 ~> _,one, decomp ~> natToBin, flatten ~> countBits.
After accepting Vitus' answer, I discovered a different way to accomplish the goal of proving a function terminates in Agda, namely using "sized types." I am providing my answer here because it seems acceptable, and also for critique of any weak points of this answer.
Sized types are described:
http://arxiv.org/pdf/1012.4896.pdf
They are implemented in Agda, not only MiniAgda; see here: http://www2.tcs.ifi.lmu.de/~abel/talkAIM2008Sendai.pdf.
The idea is to augment the data type with a size that allows the typechecker to more easily prove termination. Size is defined in the standard library.
open import Size
We define sized natural numbers:
data Nat : {i : Size} \to Set where
zero : {i : Size} \to Nat {\up i}
succ : {i : Size} \to Nat {i} \to Nat {\up i}
Next, we define predecessor and subtraction (monus):
pred : {i : Size} → Nat {i} → Nat {i}
pred .{↑ i} (zero {i}) = zero {i}
pred .{↑ i} (succ {i} n) = n
sub : {i : Size} → Nat {i} → Nat {∞} → Nat {i}
sub .{↑ i} (zero {i}) n = zero {i}
sub .{↑ i} (succ {i} m) zero = succ {i} m
sub .{↑ i} (succ {i} m) (succ n) = sub {i} m n
Now, we may define division via Euclid's algorithm:
div : {i : Size} → Nat {i} → Nat → Nat {i}
div .{↑ i} (zero {i}) n = zero {i}
div .{↑ i} (succ {i} m) n = succ {i} (div {i} (sub {i} m n) n)
data ⊥ : Set where
record ⊤ : Set where
notZero : Nat → Set
notZero zero = ⊥
notZero _ = ⊤
We give division for nonzero denominators.
If the denominator is nonzero, then it is of the form, b+1. We then do
divPos a (b+1) = div a b
Since div a b returns ceiling (a/(b+1)).
divPos : {i : Size} → Nat {i} → (m : Nat) → (notZero m) → Nat {i}
divPos a (succ b) p = div a b
divPos a zero ()
As auxiliary:
div2 : {i : Size} → Nat {i} → Nat {i}
div2 n = divPos n (succ (succ zero)) (record {})
Now we can define a divide and conquer method for computing the n-th Fibonacci number.
fibd : {i : Size} → Nat {i} → Nat
fibd zero = zero
fibd (succ zero) = succ zero
fibd (succ (succ zero)) = succ zero
fibd (succ n) with even (succ n)
fibd .{↑ i} (succ {i} n) | true =
let
-- When m=n+1, the input, is even, we set k = m/2
-- Note, ceil(m/2) = ceil(n/2)
k = div2 {i} n
fib[k-1] = fibd {i} (pred {i} k)
fib[k] = fibd {i} k
fib[k+1] = fib[k-1] + fib[k]
in
(fib[k+1] * fib[k]) + (fib[k] * fib[k-1])
fibd .{↑ i} (succ {i} n) | false =
let
-- When m=n+1, the input, is odd, we set k = n/2 = (m-1)/2.
k = div2 {i} n
fib[k-1] = fibd {i} (pred {i} k)
fib[k] = fibd {i} k
fib[k+1] = fib[k-1] + fib[k]
in
(fib[k+1] * fib[k+1]) + (fib[k] * fib[k])
You cannot do this directly: Agda's termination checker only considers recursion ok on arguments that are syntactically smaller. However, the Agda standard library provides a few modules for proving termination using a well-founded order between the arguments of the functions. The standard order on natural numbers is such an order and can be used here.
Using the code in Induction.*, you can write your function as follows:
open import Data.Nat
open import Induction.WellFounded
open import Induction.Nat
s≤′s : ∀ {n m} → n ≤′ m → suc n ≤′ suc m
s≤′s ≤′-refl = ≤′-refl
s≤′s (≤′-step lt) = ≤′-step (s≤′s lt)
proof : ∀ n → ⌊ n /2⌋ ≤′ n
proof 0 = ≤′-refl
proof 1 = ≤′-step (proof zero)
proof (suc (suc n)) = ≤′-step (s≤′s (proof n))
f : ℕ → ℕ
f = <-rec (λ _ → ℕ) helper
where
helper : (n : ℕ) → (∀ y → y <′ n → ℕ) → ℕ
helper 0 rec = 0
helper (suc n) rec = rec ⌊ n /2⌋ (s≤′s (proof n))
I found an article with some explanation here. But there may be better references out there.
A similar question appeared on the Agda mailing-list a few weeks ago and the consensus seemed to be to inject the Data.Nat element into Data.Bin and then use structural recursion on this representation which is well-suited for the job at hand.
You can find the whole thread here : http://comments.gmane.org/gmane.comp.lang.agda/5690
You can avoid using well-founded recursion. Let's say you want a function, that applies ⌊_/2⌋ to a number, until it reaches 0, and collects the results. With the {-# TERMINATING #-} pragma it can be defined like this:
{-# TERMINATING #-}
⌊_/2⌋s : ℕ -> List ℕ
⌊_/2⌋s 0 = []
⌊_/2⌋s n = n ∷ ⌊ ⌊ n /2⌋ /2⌋s
The second clause is equivalent to
⌊_/2⌋s n = n ∷ ⌊ n ∸ (n ∸ ⌊ n /2⌋) /2⌋s
It's possible to make ⌊_/2⌋s structurally recursive by inlining this substraction:
⌊_/2⌋s : ℕ -> List ℕ
⌊_/2⌋s = go 0 where
go : ℕ -> ℕ -> List ℕ
go _ 0 = []
go 0 (suc n) = suc n ∷ go (n ∸ ⌈ n /2⌉) n
go (suc i) (suc n) = go i n
go (n ∸ ⌈ n /2⌉) n is a simplified version of go (suc n ∸ ⌊ suc n /2⌋ ∸ 1) n
Some tests:
test-5 : ⌊ 5 /2⌋s ≡ 5 ∷ 2 ∷ 1 ∷ []
test-5 = refl
test-25 : ⌊ 25 /2⌋s ≡ 25 ∷ 12 ∷ 6 ∷ 3 ∷ 1 ∷ []
test-25 = refl
Now let's say you want a function, that applies ⌊_/2⌋ to a number, until it reaches 0, and sums the results. It's simply
⌊_/2⌋sum : ℕ -> ℕ
⌊ n /2⌋sum = go ⌊ n /2⌋s where
go : List ℕ -> ℕ
go [] = 0
go (n ∷ ns) = n + go ns
So we can just run our recursion on a list, that contains values, produced by the ⌊_/2⌋s function.
More concise version is
⌊ n /2⌋sum = foldr _+_ 0 ⌊ n /2⌋s
And back to the well-foundness.
open import Function
open import Relation.Nullary
open import Relation.Binary
open import Induction.WellFounded
open import Induction.Nat
calls : ∀ {a b ℓ} {A : Set a} {_<_ : Rel A ℓ} {guarded : A -> Set b}
-> (f : A -> A)
-> Well-founded _<_
-> (∀ {x} -> guarded x -> f x < x)
-> (∀ x -> Dec (guarded x))
-> A
-> List A
calls {A = A} {_<_} f wf smaller dec-guarded x = go (wf x) where
go : ∀ {x} -> Acc _<_ x -> List A
go {x} (acc r) with dec-guarded x
... | no _ = []
... | yes g = x ∷ go (r (f x) (smaller g))
This function does the same as the ⌊_/2⌋s function, i.e. produces values for recursive calls, but for any function, that satisfies certain conditions.
Look at the definition of go. If x is not guarded, then return []. Otherwise prepend x and call go on f x (we could write go {x = f x} ...), which is structurally smaller.
We can redefine ⌊_/2⌋s in terms of calls:
⌊_/2⌋s : ℕ -> List ℕ
⌊_/2⌋s = calls {guarded = ?} ⌊_/2⌋ ? ? ?
⌊ n /2⌋s returns [], only when n is 0, so guarded = λ n -> n > 0.
Our well-founded relation is based on _<′_ and defined in the Induction.Nat module as <-well-founded.
So we have
⌊_/2⌋s = calls {guarded = λ n -> n > 0} ⌊_/2⌋ <-well-founded {!!} {!!}
The type of the next hole is {x : ℕ} → x > 0 → ⌊ x /2⌋ <′ x
We can easily prove this proposition:
open import Data.Nat.Properties
suc-⌊/2⌋-≤′ : ∀ n -> ⌊ suc n /2⌋ ≤′ n
suc-⌊/2⌋-≤′ 0 = ≤′-refl
suc-⌊/2⌋-≤′ (suc n) = s≤′s (⌊n/2⌋≤′n n)
>0-⌊/2⌋-<′ : ∀ {n} -> n > 0 -> ⌊ n /2⌋ <′ n
>0-⌊/2⌋-<′ {suc n} (s≤s z≤n) = s≤′s (suc-⌊/2⌋-≤′ n)
The type of the last hole is (x : ℕ) → Dec (x > 0), we can fill it by _≤?_ 1.
And the final definition is
⌊_/2⌋s : ℕ -> List ℕ
⌊_/2⌋s = calls ⌊_/2⌋ <-well-founded >0-⌊/2⌋-<′ (_≤?_ 1)
Now you can recurse on a list, produced by ⌊_/2⌋s, without any termination issues.
I encountered this sort of problem when trying to write a quick sort function in Agda.
While other answers seem to explain the problem and solutions more generally, coming from a CS background, I think the following wording would be more accessible for certain readers:
The problem of working with the Agda termination checker comes down to how we can internalize the termination checking process.
Suppose we want to define a function
func : Some-Recursively-Defined-Type → A
func non-recursive-case = some-a
func (recursive-case n) = some-other-func (func (f n)) (func (g n)) ...
In many of the cases, we the writers know f n and g n are going to be smaller than recursive-case n. Furthermore, it is not like the proofs for these being smaller are super difficult. The problem is more about how we can communicate this knowledge to Agda.
It turns out we can do this by adding a timer argument to the definition.
Timer : Type
Timer = Nat
measure : Some-Recursively-Defined-Type → Timer
-- this function returns an upper-bound of how many steps left to terminate
-- the estimate should be tight enough for the non-recursive cases that
-- given those estimates,
-- pattern matching on recursive cases is obviously impossible
measure = {! !}
func-aux :
(timer : Timer) -- the timer,
(actual-arguments : Some-Recursively-Defined-Type)
(timer-bounding : measure actual-arguments ≤ timer)
→ A
func-aux zero non-recursive-case prf = a
-- the prf should force args to only pattern match to the non-recursive cases
func-aux (succ t) non-recursive-case prf = a
func-aux (succ t) (recursive-case n) prf =
some-other-func (func-aux t (f n) prf') (func-aux t (g n) prf'') ... where
prf' : measure (f n) ≤ t
prf' = {! !}
prf'' : measure (g n) ≤ t
prf'' = {! !}
With these at hand, we can define the function we want as something like the following :
func : Some-Recursively-Defined-Type → A
func x with measure x
func x | n = func-aux n x (≤-is-reflexive n)
Caveat
I have not taken into account anything about whether the computation would be efficient.
While Timer type is not restricted to be Nat (but for all types with which we have a strong enough order relation to work with), I think it is pretty safe to say we don't gain much even if we consider such generality.