-(******************************************************************************)
-(* General Data Structures *)
-(******************************************************************************)
-
-Require Import Coq.Unicode.Utf8.
-Require Import Coq.Classes.RelationClasses.
-Require Import Coq.Classes.Morphisms.
-Require Import Coq.Setoids.Setoid.
-Require Import Coq.Strings.String.
-Require Setoid.
-Require Import Coq.Lists.List.
-Require Import Preamble.
-Generalizable All Variables.
-Require Import Omega.
-
-
-Class EqDecidable (T:Type) :=
-{ eqd_type := T
-; eqd_dec : forall v1 v2:T, sumbool (v1=v2) (not (v1=v2))
-; eqd_dec_reflexive : forall v, (eqd_dec v v) = (left _ (refl_equal _))
-}.
-Coercion eqd_type : EqDecidable >-> Sortclass.
-
-
-(*******************************************************************************)
-(* Trees *)
-
-Inductive Tree (a:Type) : Type :=
- | T_Leaf : a -> Tree a
- | T_Branch : Tree a -> Tree a -> Tree a.
-Implicit Arguments T_Leaf [ a ].
-Implicit Arguments T_Branch [ a ].
-
-Notation "a ,, b" := (@T_Branch _ a b) : tree_scope.
-
-(* tree-of-option-of-X comes up a lot, so we give it special notations *)
-Notation "[ q ]" := (@T_Leaf (option _) (Some q)) : tree_scope.
-Notation "[ ]" := (@T_Leaf (option _) None) : tree_scope.
-Notation "[]" := (@T_Leaf (option _) None) : tree_scope.
-
-Open Scope tree_scope.
-
-Fixpoint mapTree {a b:Type}(f:a->b)(t:@Tree a) : @Tree b :=
- match t with
- | T_Leaf x => T_Leaf (f x)
- | T_Branch l r => T_Branch (mapTree f l) (mapTree f r)
- end.
-Fixpoint mapOptionTree {a b:Type}(f:a->b)(t:@Tree ??a) : @Tree ??b :=
- match t with
- | T_Leaf None => T_Leaf None
- | T_Leaf (Some x) => T_Leaf (Some (f x))
- | T_Branch l r => T_Branch (mapOptionTree f l) (mapOptionTree f r)
- end.
-Fixpoint mapTreeAndFlatten {a b:Type}(f:a->@Tree b)(t:@Tree a) : @Tree b :=
- match t with
- | T_Leaf x => f x
- | T_Branch l r => T_Branch (mapTreeAndFlatten f l) (mapTreeAndFlatten f r)
- end.
-Fixpoint mapOptionTreeAndFlatten {a b:Type}(f:a->@Tree ??b)(t:@Tree ??a) : @Tree ??b :=
- match t with
- | T_Leaf None => []
- | T_Leaf (Some x) => f x
- | T_Branch l r => T_Branch (mapOptionTreeAndFlatten f l) (mapOptionTreeAndFlatten f r)
- end.
-Fixpoint treeReduce {T:Type}{R:Type}(mapLeaf:T->R)(mergeBranches:R->R->R) (t:Tree T) :=
- match t with
- | T_Leaf x => mapLeaf x
- | T_Branch y z => mergeBranches (treeReduce mapLeaf mergeBranches y) (treeReduce mapLeaf mergeBranches z)
- end.
-Definition treeDecomposition {D T:Type} (mapLeaf:T->D) (mergeBranches:D->D->D) :=
- forall d:D, { tt:Tree T & d = treeReduce mapLeaf mergeBranches tt }.
-
-Lemma tree_dec_eq :
- forall {Q}(t1 t2:Tree ??Q),
- (forall q1 q2:Q, sumbool (q1=q2) (not (q1=q2))) ->
- sumbool (t1=t2) (not (t1=t2)).
- intro Q.
- intro t1.
- induction t1; intros.
-
- destruct a; destruct t2.
- destruct o.
- set (X q q0) as X'.
- inversion X'; subst.
- left; auto.
- right; unfold not; intro; apply H. inversion H0; subst. auto.
- right. unfold not; intro; inversion H.
- right. unfold not; intro; inversion H.
- destruct o.
- right. unfold not; intro; inversion H.
- left; auto.
- right. unfold not; intro; inversion H.
-
- destruct t2.
- right. unfold not; intro; inversion H.
- set (IHt1_1 t2_1 X) as X1.
- set (IHt1_2 t2_2 X) as X2.
- destruct X1; destruct X2; subst.
- left; auto.
-
- right.
- unfold not; intro H.
- apply n.
- inversion H; auto.
-
- right.
- unfold not; intro H.
- apply n.
- inversion H; auto.
-
- right.
- unfold not; intro H.
- apply n.
- inversion H; auto.
- Defined.
-
-
-
-
-(*******************************************************************************)
-(* Lists *)
-
-Notation "a :: b" := (cons a b) : list_scope.
-Open Scope list_scope.
-Fixpoint leaves {a:Type}(t:Tree (option a)) : list a :=
- match t with
- | (T_Leaf l) => match l with
- | None => nil
- | Some x => x::nil
- end
- | (T_Branch l r) => app (leaves l) (leaves r)
- end.
-(* weak inverse of "leaves" *)
-Fixpoint unleaves {A:Type}(l:list A) : Tree (option A) :=
- match l with
- | nil => []
- | (a::b) => [a],,(unleaves b)
- end.
-
-(* a map over a list and the conjunction of the results *)
-Fixpoint mapProp {A:Type} (f:A->Prop) (l:list A) : Prop :=
- match l with
- | nil => True
- | (a::al) => f a /\ mapProp f al
- end.
-
-Lemma map_id : forall A (l:list A), (map (fun x:A => x) l) = l.
- induction l.
- auto.
- simpl.
- rewrite IHl.
- auto.
- Defined.
-Lemma map_app : forall `(f:A->B) l l', map f (app l l') = app (map f l) (map f l').
- intros.
- induction l; auto.
- simpl.
- rewrite IHl.
- auto.
- Defined.
-Lemma map_compose : forall A B C (f:A->B)(g:B->C)(l:list A),
- (map (g ○ f) l) = (map g (map f l)).
- intros.
- induction l.
- simpl; auto.
- simpl.
- rewrite IHl.
- auto.
- Defined.
-Lemma list_cannot_be_longer_than_itself : forall `(a:A)(b:list A), b = (a::b) -> False.
- intros.
- induction b.
- inversion H.
- inversion H. apply IHb in H2.
- auto.
- Defined.
-Lemma list_cannot_be_longer_than_itself' : forall A (b:list A) (a c:A), b = (a::c::b) -> False.
- induction b.
- intros; inversion H.
- intros.
- inversion H.
- apply IHb in H2.
- auto.
- Defined.
-
-Lemma mapOptionTree_on_nil : forall `(f:A->B) h, [] = mapOptionTree f h -> h=[].
- intros.
- destruct h.
- destruct o. inversion H.
- auto.
- inversion H.
- Defined.
-
-Lemma mapOptionTree_comp a b c (f:a->b) (g:b->c) q : (mapOptionTree g (mapOptionTree f q)) = mapOptionTree (g ○ f) q.
- induction q.
- destruct a0; simpl.
- reflexivity.
- reflexivity.
- simpl.
- rewrite IHq1.
- rewrite IHq2.
- reflexivity.
- Qed.
-
-(* handy facts: map preserves the length of a list *)
-Lemma map_on_nil : forall A B (s1:list A) (f:A->B), nil = map f s1 -> s1=nil.
- intros.
- induction s1.
- auto.
- assert False.
- simpl in H.
- inversion H.
- inversion H0.
- Defined.
-Lemma map_on_singleton : forall A B (f:A->B) x (s1:list A), (cons x nil) = map f s1 -> { y : A & s1=(cons y nil) & (f y)=x }.
- induction s1.
- intros.
- simpl in H; assert False. inversion H. inversion H0.
- clear IHs1.
- intros.
- exists a.
- simpl in H.
- assert (s1=nil).
- inversion H. apply map_on_nil in H2. auto.
- subst.
- auto.
- assert (s1=nil).
- inversion H. apply map_on_nil in H2. auto.
- subst.
- simpl in H.
- inversion H. auto.
- Defined.
-
-Lemma map_on_doubleton : forall A B (f:A->B) x y (s1:list A), ((x::y::nil) = map f s1) ->
- { z : A*A & s1=((fst z)::(snd z)::nil) & (f (fst z))=x /\ (f (snd z))=y }.
- intros.
- destruct s1.
- inversion H.
- destruct s1.
- inversion H.
- destruct s1.
- inversion H.
- exists (a,a0); auto.
- simpl in H.
- inversion H.
- Defined.
-
-
-Lemma mapTree_compose : forall A B C (f:A->B)(g:B->C)(l:Tree A),
- (mapTree (g ○ f) l) = (mapTree g (mapTree f l)).
- induction l.
- reflexivity.
- simpl.
- rewrite IHl1.
- rewrite IHl2.
- reflexivity.
- Defined.
-
-Lemma lmap_compose : forall A B C (f:A->B)(g:B->C)(l:list A),
- (map (g ○ f) l) = (map g (map f l)).
- intros.
- induction l.
- simpl; auto.
- simpl.
- rewrite IHl.
- auto.
- Defined.
-
-(* sends a::b::c::nil to [[[[],,c],,b],,a] *)
-Fixpoint unleaves' {A:Type}(l:list A) : Tree (option A) :=
- match l with
- | nil => []
- | (a::b) => (unleaves' b),,[a]
- end.
-
-(* sends a::b::c::nil to [[[[],,c],,b],,a] *)
-Fixpoint unleaves'' {A:Type}(l:list ??A) : Tree ??A :=
- match l with
- | nil => []
- | (a::b) => (unleaves'' b),,(T_Leaf a)
- end.
-
-Fixpoint filter {T:Type}(l:list ??T) : list T :=
- match l with
- | nil => nil
- | (None::b) => filter b
- | ((Some x)::b) => x::(filter b)
- end.
-
-Inductive distinct {T:Type} : list T -> Prop :=
-| distinct_nil : distinct nil
-| distinct_cons : forall a ax, (@In _ a ax -> False) -> distinct ax -> distinct (a::ax).
-
-Lemma map_preserves_length {A}{B}(f:A->B)(l:list A) : (length l) = (length (map f l)).
- induction l; auto.
- simpl.
- omega.
- Qed.
-
-(* decidable quality on a list of elements which have decidable equality *)
-Definition list_eq_dec : forall {T:Type}(l1 l2:list T)(dec:forall t1 t2:T, sumbool (eq t1 t2) (not (eq t1 t2))),
- sumbool (eq l1 l2) (not (eq l1 l2)).
- intro T.
- intro l1.
- induction l1; intros.
- destruct l2.
- left; reflexivity.
- right; intro H; inversion H.
- destruct l2 as [| b l2].
- right; intro H; inversion H.
- set (IHl1 l2 dec) as eqx.
- destruct eqx.
- subst.
- set (dec a b) as eqy.
- destruct eqy.
- subst.
- left; reflexivity.
- right. intro. inversion H. subst. apply n. auto.
- right.
- intro.
- inversion H.
- apply n.
- auto.
- Defined.
-
-
-
-
-(*******************************************************************************)
-(* Length-Indexed Lists *)
-
-Inductive vec (A:Type) : nat -> Type :=
-| vec_nil : vec A 0
-| vec_cons : forall n, A -> vec A n -> vec A (S n).
-
-Fixpoint vec2list {n:nat}{t:Type}(v:vec t n) : list t :=
- match v with
- | vec_nil => nil
- | vec_cons n a va => a::(vec2list va)
- end.
-
-Require Import Omega.
-Definition vec_get : forall {T:Type}{l:nat}(v:vec T l)(n:nat)(pf:lt n l), T.
- intro T.
- intro len.
- intro v.
- induction v; intros.
- assert False.
- inversion pf.
- inversion H.
- rename n into len.
- destruct n0 as [|n].
- exact a.
- apply (IHv n).
- omega.
- Defined.
-
-Definition vec_zip {n:nat}{A B:Type}(va:vec A n)(vb:vec B n) : vec (A*B) n.
- induction n.
- apply vec_nil.
- inversion va; subst.
- inversion vb; subst.
- apply vec_cons; auto.
- Defined.
-
-Definition vec_map {n:nat}{A B:Type}(f:A->B)(v:vec A n) : vec B n.
- induction n.
- apply vec_nil.
- inversion v; subst.
- apply vec_cons; auto.
- Defined.
-
-Fixpoint vec_In {A:Type} {n:nat} (a:A) (l:vec A n) : Prop :=
- match l with
- | vec_nil => False
- | vec_cons _ n m => (n = a) \/ vec_In a m
- end.
-Implicit Arguments vec_nil [ A ].
-Implicit Arguments vec_cons [ A n ].
-
-Definition append_vec {n:nat}{T:Type}(v:vec T n)(t:T) : vec T (S n).
- induction n.
- apply (vec_cons t vec_nil).
- apply vec_cons; auto.
- Defined.
-
-Definition list2vec {T:Type}(l:list T) : vec T (length l).
- induction l.
- apply vec_nil.
- apply vec_cons; auto.
- Defined.
-
-Definition vec_head {n:nat}{T}(v:vec T (S n)) : T.
- inversion v; auto.
- Defined.
-Definition vec_tail {n:nat}{T}(v:vec T (S n)) : vec T n.
- inversion v; auto.
- Defined.
-
-Lemma vec_chop {T}{l1 l2:list T}{Q}(v:vec Q (length (app l1 l2))) : vec Q (length l1).
- induction l1.
- apply vec_nil.
- apply vec_cons.
- simpl in *.
- inversion v; subst; auto.
- apply IHl1.
- inversion v; subst; auto.
- Defined.
-
-Lemma vec_chop' {T}{l1 l2:list T}{Q}(v:vec Q (length (app l1 l2))) : vec Q (length l2).
- induction l1.
- apply v.
- simpl in *.
- apply IHl1; clear IHl1.
- inversion v; subst; auto.
- Defined.
-
-Notation "a ::: b" := (@vec_cons _ _ a b) (at level 20).
-
-
-
-(*******************************************************************************)
-(* Shaped Trees *)
-
-(* a ShapedTree is a tree indexed by the shape (but not the leaf values) of another tree; isomorphic to (ITree (fun _ => Q)) *)
-Inductive ShapedTree {T:Type}(Q:Type) : Tree ??T -> Type :=
-| st_nil : @ShapedTree T Q []
-| st_leaf : forall {t}, Q -> @ShapedTree T Q [t]
-| st_branch : forall {t1}{t2}, @ShapedTree T Q t1 -> @ShapedTree T Q t2 -> @ShapedTree T Q (t1,,t2).
-
-Fixpoint unshape {T:Type}{Q:Type}{idx:Tree ??T}(st:@ShapedTree T Q idx) : Tree ??Q :=
-match st with
-| st_nil => []
-| st_leaf _ q => [q]
-| st_branch _ _ b1 b2 => (unshape b1),,(unshape b2)
-end.
-
-Definition mapShapedTree {T}{idx:Tree ??T}{V}{Q}(f:V->Q)(st:ShapedTree V idx) : ShapedTree Q idx.
- induction st.
- apply st_nil.
- apply st_leaf. apply f. apply q.
- apply st_branch; auto.
- Defined.
-
-Definition zip_shapedTrees {T:Type}{Q1 Q2:Type}{idx:Tree ??T}
- (st1:ShapedTree Q1 idx)(st2:ShapedTree Q2 idx) : ShapedTree (Q1*Q2) idx.
- induction idx.
- destruct a.
- apply st_leaf; auto.
- inversion st1.
- inversion st2.
- auto.
- apply st_nil.
- apply st_branch; auto.
- inversion st1; subst; apply IHidx1; auto.
- inversion st2; subst; auto.
- inversion st2; subst; apply IHidx2; auto.
- inversion st1; subst; auto.
- Defined.
-
-Definition build_shapedTree {T:Type}(idx:Tree ??T){Q:Type}(f:T->Q) : ShapedTree Q idx.
- induction idx.
- destruct a.
- apply st_leaf; auto.
- apply st_nil.
- apply st_branch; auto.
- Defined.
-
-Lemma unshape_map : forall {Q}{b}(f:Q->b){T}{idx:Tree ??T}(t:ShapedTree Q idx),
- mapOptionTree f (unshape t) = unshape (mapShapedTree f t).
- intros.
- induction t; auto.
- simpl.
- rewrite IHt1.
- rewrite IHt2.
- reflexivity.
- Qed.
-
-
-
-
-(*******************************************************************************)
-(* Type-Indexed Lists *)
-
-(* an indexed list *)
-Inductive IList (I:Type)(F:I->Type) : list I -> Type :=
-| INil : IList I F nil
-| ICons : forall i is, F i -> IList I F is -> IList I F (i::is).
-Implicit Arguments INil [ I F ].
-Implicit Arguments ICons [ I F ].
-
-(* a tree indexed by a (Tree (option X)) *)
-Inductive ITree (I:Type)(F:I->Type) : Tree ??I -> Type :=
-| INone : ITree I F []
-| ILeaf : forall i: I, F i -> ITree I F [i]
-| IBranch : forall it1 it2:Tree ??I, ITree I F it1 -> ITree I F it2 -> ITree I F (it1,,it2).
-Implicit Arguments INil [ I F ].
-Implicit Arguments ILeaf [ I F ].
-Implicit Arguments IBranch [ I F ].
-
-
-
-
-(*******************************************************************************)
-(* Extensional equality on functions *)
-
-Definition extensionality := fun (t1 t2:Type) => (fun (f:t1->t2) g => forall x:t1, (f x)=(g x)).
-Hint Transparent extensionality.
-Instance extensionality_Equivalence : forall t1 t2, Equivalence (extensionality t1 t2).
- intros; apply Build_Equivalence;
- intros; compute; intros; auto.
- rewrite H; rewrite H0; auto.
- Defined.
- Add Parametric Morphism (A B C:Type) : (fun f g => g ○ f)
- with signature (extensionality A B ==> extensionality B C ==> extensionality A C) as parametric_morphism_extensionality.
- unfold extensionality; intros; rewrite (H x1); rewrite (H0 (y x1)); auto.
- Defined.
-Lemma extensionality_composes : forall t1 t2 t3 (f f':t1->t2) (g g':t2->t3),
- (extensionality _ _ f f') ->
- (extensionality _ _ g g') ->
- (extensionality _ _ (g ○ f) (g' ○ f')).
- intros.
- unfold extensionality.
- unfold extensionality in H.
- unfold extensionality in H0.
- intros.
- rewrite H.
- rewrite H0.
- auto.
- Qed.
-
-
-
-
-
-
-(* the Error monad *)
-Inductive OrError (T:Type) :=
-| Error : forall error_message:string, OrError T
-| OK : T -> OrError T.
-Notation "??? T" := (OrError T) (at level 10).
-Implicit Arguments Error [T].
-Implicit Arguments OK [T].
-
-Definition orErrorBind {T:Type} (oe:OrError T) {Q:Type} (f:T -> OrError Q) :=
- match oe with
- | Error s => Error s
- | OK t => f t
- end.
-Notation "a >>= b" := (@orErrorBind _ a _ b) (at level 20).
-
-Fixpoint list2vecOrError {T}(l:list T)(n:nat) : ???(vec T n) :=
- match n as N return ???(vec _ N) with
- | O => match l with
- | nil => OK vec_nil
- | _ => Error "list2vecOrError: list was too long"
- end
- | S n' => match l with
- | nil => Error "list2vecOrError: list was too short"
- | t::l' => list2vecOrError l' n' >>= fun l'' => OK (vec_cons t l'')
- end
- end.
-
-Inductive Indexed {T:Type}(f:T -> Type) : ???T -> Type :=
-| Indexed_Error : forall error_message:string, Indexed f (Error error_message)
-| Indexed_OK : forall t, f t -> Indexed f (OK t)
-.
-Ltac xauto := try apply Indexed_Error; try apply Indexed_OK.
-
-
-
-
-
-
-(* for a type with decidable equality, we can maintain lists of distinct elements *)
-Section DistinctList.
- Context `{V:EqDecidable}.
-
- Fixpoint addToDistinctList (cv:V)(cvl:list V) :=
- match cvl with
- | nil => cv::nil
- | cv'::cvl' => if eqd_dec cv cv' then cvl' else cv'::(addToDistinctList cv cvl')
- end.
-
- Fixpoint removeFromDistinctList (cv:V)(cvl:list V) :=
- match cvl with
- | nil => nil
- | cv'::cvl' => if eqd_dec cv cv' then removeFromDistinctList cv cvl' else cv'::(removeFromDistinctList cv cvl')
- end.
-
- Fixpoint removeFromDistinctList' (cvrem:list V)(cvl:list V) :=
- match cvrem with
- | nil => cvl
- | rem::cvrem' => removeFromDistinctList rem (removeFromDistinctList' cvrem' cvl)
- end.
-
- Fixpoint mergeDistinctLists (cvl1:list V)(cvl2:list V) :=
- match cvl1 with
- | nil => cvl2
- | cv'::cvl' => mergeDistinctLists cvl' (addToDistinctList cv' cvl2)
- end.
-End DistinctList.