mukeshtiwari/MemoBinTree.v

## MemoBinTree.v
(* In relation to https://cstheory.stackexchange.com/questions/40631/how-can-you-build-a-coinductive-memoization-table-for-recursive-functions-over-b *)
Require Import Vectors.Vector.
Import VectorNotations.

Set Primitive Projections.
Set Implicit Arguments.

Inductive binTree : Set :=
| Leaf : binTree
| Branch : binTree -> binTree -> binTree.

Inductive filterZero (A : nat -> Type) : nat -> Type :=
| FilterZero : filterZero A 0
| NonZero : forall m, (A m) -> filterZero A (S m).

Definition getNonZero A n (w : filterZero A (S n)) : A n.
inversion_clear w as [|m a].
apply a.
Defined.

(* memoVBinTree A n is intended to be isomorphic to Vector.t BinTree n -> A *)
CoInductive memoVBinTree (A : Type) (n : nat) : Type :=
 { extract    : if n then A else unit
 ; memoLeaf   : filterZero (memoVBinTree A) n
 ; memoBranch : filterZero (fun _ => memoVBinTree A (S n)) n
 }.

(* memoBinTree A is intended to be isomorphic to BinTree -> A *)
Definition memoBinTree A := memoVBinTree A 1.

Definition branch {A R n} (k : memoVBinTree A n -> memoVBinTree A (S (S n)) -> R)
 (t : memoVBinTree A (S n)) : R :=
 k (getNonZero (memoLeaf t)) (getNonZero (memoBranch t)).

CoFixpoint map {A B n} (f : A -> B) (t : memoVBinTree A n) : memoVBinTree B n :=
{| extract    := (if n return (memoVBinTree A n -> if n then B else unit)
                       then fun t => f (extract t)
                       else fun _ => tt) t
 ; memoLeaf   := (match n return (memoVBinTree A n -> filterZero (memoVBinTree B) n) with
                  | 0 =>    fun _ => FilterZero _
                  | S n0 => fun t => NonZero _ _ (map f (getNonZero (memoLeaf t)))
                  end) t
 ; memoBranch := (if n return (memoVBinTree A n -> filterZero (fun _ => memoVBinTree B (S n)) n)
                       then fun _ => FilterZero _
                       else fun t => NonZero _ _ (map f (getNonZero (memoBranch t)))) t
 |}.

CoFixpoint zip {A B C n m} (f : A -> B -> C)
  (ta : memoVBinTree A n) (tb : memoVBinTree B m) : memoVBinTree C (n + m) :=
{| extract    := (if n return (memoVBinTree A n -> if (n + m) then C else unit)
                       then fun ta => (if m return (memoVBinTree B m -> if (0 + m) then C else unit)
                                           then fun tb => f (extract ta) (extract tb)
                                           else fun _ => tt) tb
                       else fun _ => tt) ta
 ; memoLeaf   := (match n return (memoVBinTree A n -> filterZero (memoVBinTree C) (n + m)) with
                  | 0 =>    fun ta => memoLeaf (map (f (extract ta)) tb)
                  | S n0 => fun ta => NonZero _ _ (zip f (getNonZero (memoLeaf ta)) tb)
                  end) ta
 ; memoBranch := (if n return (memoVBinTree A n -> filterZero (fun _ => memoVBinTree C (S n + m)) (n + m))
                       then fun ta => memoBranch (map (f (extract ta)) tb)
                       else fun ta => NonZero _ _ (zip f (getNonZero (memoBranch ta)) tb)) ta
 |}.


CoFixpoint split {A} n m (t : memoVBinTree A (n + m)) : memoVBinTree (memoVBinTree A m) n :=
{| extract    := (if n return (memoVBinTree A (n + m) -> if n then (memoVBinTree A m) else unit)
                       then fun t => t
                       else fun _ => tt) t
 ; memoLeaf   := (match n return (memoVBinTree A (n + m) -> filterZero (memoVBinTree (memoVBinTree A m)) n) with
                  | 0 =>    fun _ => FilterZero _
                  | S n0 => fun t => NonZero _ _ (split _ _ (getNonZero (memoLeaf t)))
                  end) t
 ; memoBranch := (match n return (memoVBinTree A (n + m) -> filterZero (fun _ => memoVBinTree (memoVBinTree A m) (S n)) n) with
                  | 0 =>    fun _ => FilterZero _
                  | S n0 => fun t => NonZero _ _ (split (S (S n0)) m (getNonZero (memoBranch t)))
                  end) t
 |}.

CoFixpoint trie {A n} (f : Vector.t binTree n -> A) : memoVBinTree A n :=
{| extract    := (if n return ((Vector.t binTree n -> A) -> if n then A else unit)
                       then fun f => f (nil binTree)
                       else fun _ => tt) f
 ; memoLeaf   := (match n return ((Vector.t binTree n -> A) -> filterZero (memoVBinTree A) n) with
                  | 0 =>    fun _ => FilterZero _
                  | S n0 => fun f => NonZero _ _ (trie (fun v => f (cons _ Leaf _ v)))
                  end) f
 ; memoBranch := (if n return ((Vector.t binTree n -> A) -> filterZero (fun _ => memoVBinTree A (S n)) n)
                       then fun _ => FilterZero _
                       else fun f => NonZero _ _ (trie (fun v => f (cons _ (Branch (hd v) (hd (tl v))) _ (tl (tl v)))))) f
 |}.

Fixpoint untrie (t : binTree) : forall {A}, (memoBinTree A) -> A :=
 fun A => branch (fun l b =>
  match t with
  | Leaf => extract l
  | Branch tl tr => untrie tl (map (untrie tr) (split 1 1 b))
  end).

(*
 * Example.
 *)

Require Import ZArith.

(* This operation could stand to be a bit more expensive *)
Definition op (x y : Z) : Z := Z.modulo ((x + y + 1)*(x + y)/2 + y) 18446744073709551557%Z.

Fixpoint foldOp (t : binTree) : Z :=
match t with
| Leaf => 2147483647%Z
| Branch tl tr => op (foldOp tl) (foldOp tr)
end.

Fixpoint fullTree (n : nat) : binTree :=
match n with
| 0 => Leaf
| (S n0) => let rec := fullTree n0 in Branch rec rec
end.

(* memoTrie, but with no sharing for recursive calls of foldOp *)
Definition memoOp : memoBinTree Z := trie (fun v => foldOp (hd v)).

Definition memoFoldOp (t : binTree) : Z := untrie t memoOp.

Eval vm_compute in (memoFoldOp (fullTree 0)).
Time Eval vm_compute in memoFoldOp (fullTree 12).
Time Eval vm_compute in memoFoldOp (fullTree 11).
Time Eval vm_compute in memoFoldOp (fullTree 12).
Time Eval vm_compute in memoFoldOp (fullTree 11).
Time Eval vm_compute in (memoFoldOp (fullTree 13),memoFoldOp (fullTree 13)).
Time Eval vm_compute in (foldOp (fullTree 13),foldOp (fullTree 13)).

(* This memotrie doesn't satisfy the guard condition.
 * Coq doesn't know that zip has a sufficent modulus of continuity.
 *)
CoFixpoint memoOpX : memoBinTree Z :=
  @Build_memoVBinTree Z 1 tt
    (NonZero _ _ (@Build_memoVBinTree Z 0 2147483647%Z (FilterZero _) (FilterZero _)))
    (NonZero _ _ (zip op memoOpX memoOpX)).
	(* In relation to https://cstheory.stackexchange.com/questions/40631/how-can-you-build-a-coinductive-memoization-table-for-recursive-functions-over-b *)
	Require Import Vectors.Vector.
	Import VectorNotations.

	Set Primitive Projections.
	Set Implicit Arguments.

	Inductive binTree : Set :=
	\| Leaf : binTree
	\| Branch : binTree -> binTree -> binTree.

	Inductive filterZero (A : nat -> Type) : nat -> Type :=
	\| FilterZero : filterZero A 0
	\| NonZero : forall m, (A m) -> filterZero A (S m).

	Definition getNonZero A n (w : filterZero A (S n)) : A n.
	inversion_clear w as [\|m a].
	apply a.
	Defined.

	(* memoVBinTree A n is intended to be isomorphic to Vector.t BinTree n -> A *)
	CoInductive memoVBinTree (A : Type) (n : nat) : Type :=
	{ extract : if n then A else unit
	; memoLeaf : filterZero (memoVBinTree A) n
	; memoBranch : filterZero (fun _ => memoVBinTree A (S n)) n
	}.

	(* memoBinTree A is intended to be isomorphic to BinTree -> A *)
	Definition memoBinTree A := memoVBinTree A 1.

	Definition branch {A R n} (k : memoVBinTree A n -> memoVBinTree A (S (S n)) -> R)
	(t : memoVBinTree A (S n)) : R :=
	k (getNonZero (memoLeaf t)) (getNonZero (memoBranch t)).

	CoFixpoint map {A B n} (f : A -> B) (t : memoVBinTree A n) : memoVBinTree B n :=
	{\| extract := (if n return (memoVBinTree A n -> if n then B else unit)
	then fun t => f (extract t)
	else fun _ => tt) t
	; memoLeaf := (match n return (memoVBinTree A n -> filterZero (memoVBinTree B) n) with
	\| 0 => fun _ => FilterZero _
	\| S n0 => fun t => NonZero _ _ (map f (getNonZero (memoLeaf t)))
	end) t
	; memoBranch := (if n return (memoVBinTree A n -> filterZero (fun _ => memoVBinTree B (S n)) n)
	then fun _ => FilterZero _
	else fun t => NonZero _ _ (map f (getNonZero (memoBranch t)))) t
	\|}.

	CoFixpoint zip {A B C n m} (f : A -> B -> C)
	(ta : memoVBinTree A n) (tb : memoVBinTree B m) : memoVBinTree C (n + m) :=
	{\| extract := (if n return (memoVBinTree A n -> if (n + m) then C else unit)
	then fun ta => (if m return (memoVBinTree B m -> if (0 + m) then C else unit)
	then fun tb => f (extract ta) (extract tb)
	else fun _ => tt) tb
	else fun _ => tt) ta
	; memoLeaf := (match n return (memoVBinTree A n -> filterZero (memoVBinTree C) (n + m)) with
	\| 0 => fun ta => memoLeaf (map (f (extract ta)) tb)
	\| S n0 => fun ta => NonZero _ _ (zip f (getNonZero (memoLeaf ta)) tb)
	end) ta
	; memoBranch := (if n return (memoVBinTree A n -> filterZero (fun _ => memoVBinTree C (S n + m)) (n + m))
	then fun ta => memoBranch (map (f (extract ta)) tb)
	else fun ta => NonZero _ _ (zip f (getNonZero (memoBranch ta)) tb)) ta
	\|}.


	CoFixpoint split {A} n m (t : memoVBinTree A (n + m)) : memoVBinTree (memoVBinTree A m) n :=
	{\| extract := (if n return (memoVBinTree A (n + m) -> if n then (memoVBinTree A m) else unit)
	then fun t => t
	else fun _ => tt) t
	; memoLeaf := (match n return (memoVBinTree A (n + m) -> filterZero (memoVBinTree (memoVBinTree A m)) n) with
	\| 0 => fun _ => FilterZero _
	\| S n0 => fun t => NonZero _ _ (split _ _ (getNonZero (memoLeaf t)))
	end) t
	; memoBranch := (match n return (memoVBinTree A (n + m) -> filterZero (fun _ => memoVBinTree (memoVBinTree A m) (S n)) n) with
	\| 0 => fun _ => FilterZero _
	\| S n0 => fun t => NonZero _ _ (split (S (S n0)) m (getNonZero (memoBranch t)))
	end) t
	\|}.

	CoFixpoint trie {A n} (f : Vector.t binTree n -> A) : memoVBinTree A n :=
	{\| extract := (if n return ((Vector.t binTree n -> A) -> if n then A else unit)
	then fun f => f (nil binTree)
	else fun _ => tt) f
	; memoLeaf := (match n return ((Vector.t binTree n -> A) -> filterZero (memoVBinTree A) n) with
	\| 0 => fun _ => FilterZero _
	\| S n0 => fun f => NonZero _ _ (trie (fun v => f (cons _ Leaf _ v)))
	end) f
	; memoBranch := (if n return ((Vector.t binTree n -> A) -> filterZero (fun _ => memoVBinTree A (S n)) n)
	then fun _ => FilterZero _
	else fun f => NonZero _ _ (trie (fun v => f (cons _ (Branch (hd v) (hd (tl v))) _ (tl (tl v)))))) f
	\|}.

	Fixpoint untrie (t : binTree) : forall {A}, (memoBinTree A) -> A :=
	fun A => branch (fun l b =>
	match t with
	\| Leaf => extract l
	\| Branch tl tr => untrie tl (map (untrie tr) (split 1 1 b))
	end).

	(*
	* Example.
	*)

	Require Import ZArith.

	(* This operation could stand to be a bit more expensive *)
	Definition op (x y : Z) : Z := Z.modulo ((x + y + 1)*(x + y)/2 + y) 18446744073709551557%Z.

	Fixpoint foldOp (t : binTree) : Z :=
	match t with
	\| Leaf => 2147483647%Z
	\| Branch tl tr => op (foldOp tl) (foldOp tr)
	end.

	Fixpoint fullTree (n : nat) : binTree :=
	match n with
	\| 0 => Leaf
	\| (S n0) => let rec := fullTree n0 in Branch rec rec
	end.

	(* memoTrie, but with no sharing for recursive calls of foldOp *)
	Definition memoOp : memoBinTree Z := trie (fun v => foldOp (hd v)).

	Definition memoFoldOp (t : binTree) : Z := untrie t memoOp.

	Eval vm_compute in (memoFoldOp (fullTree 0)).
	Time Eval vm_compute in memoFoldOp (fullTree 12).
	Time Eval vm_compute in memoFoldOp (fullTree 11).
	Time Eval vm_compute in memoFoldOp (fullTree 12).
	Time Eval vm_compute in memoFoldOp (fullTree 11).
	Time Eval vm_compute in (memoFoldOp (fullTree 13),memoFoldOp (fullTree 13)).
	Time Eval vm_compute in (foldOp (fullTree 13),foldOp (fullTree 13)).

	(* This memotrie doesn't satisfy the guard condition.
	* Coq doesn't know that zip has a sufficent modulus of continuity.
	*)
	CoFixpoint memoOpX : memoBinTree Z :=
	@Build_memoVBinTree Z 1 tt
	(NonZero _ _ (@Build_memoVBinTree Z 0 2147483647%Z (FilterZero _) (FilterZero _)))
	(NonZero _ _ (zip op memoOpX memoOpX)).