Constructions of semi-lattices.
Require Import Coqlib.
Require Import Maps.
Require Import FSets.
Local Unset Elimination Schemes.
Local Unset Case Analysis Schemes.
Signatures of semi-lattices
A semi-lattice is a type t equipped with an equivalence relation eq,
a boolean equivalence test beq, a partial order ge, a smallest element
bot, and an upper bound operation lub.
Note that we do not demand that lub computes the least upper bound.
Module Type SEMILATTICE.
Parameter t:
Type.
Parameter eq:
t ->
t ->
Prop.
Axiom eq_refl:
forall x,
eq x x.
Axiom eq_sym:
forall x y,
eq x y ->
eq y x.
Axiom eq_trans:
forall x y z,
eq x y ->
eq y z ->
eq x z.
Parameter beq:
t ->
t ->
bool.
Axiom beq_correct:
forall x y,
beq x y =
true ->
eq x y.
Parameter ge:
t ->
t ->
Prop.
Axiom ge_refl:
forall x y,
eq x y ->
ge x y.
Axiom ge_trans:
forall x y z,
ge x y ->
ge y z ->
ge x z.
Parameter bot:
t.
Axiom ge_bot:
forall x,
ge x bot.
Parameter lub:
t ->
t ->
t.
Axiom ge_lub_left:
forall x y,
ge (
lub x y)
x.
Axiom ge_lub_right:
forall x y,
ge (
lub x y)
y.
End SEMILATTICE.
A semi-lattice ``with top'' is similar, but also has a greatest
element top.
Module Type SEMILATTICE_WITH_TOP.
Include SEMILATTICE.
Parameter top:
t.
Axiom ge_top:
forall x,
ge top x.
End SEMILATTICE_WITH_TOP.
Semi-lattice over maps
Set Implicit Arguments.
Given a semi-lattice (without top) L, the following functor implements
a semi-lattice structure over finite maps from positive numbers to L.t.
The default value for these maps is L.bot. Bottom elements are not smashed.
Module LPMap1(
L:
SEMILATTICE) <:
SEMILATTICE.
Definition t :=
PTree.t L.t.
Definition get (
p:
positive) (
x:
t) :
L.t :=
match x!
p with None =>
L.bot |
Some x =>
x end.
Definition set (
p:
positive) (
v:
L.t) (
x:
t) :
t :=
if L.beq v L.bot
then PTree.remove p x
else PTree.set p v x.
Lemma gsspec:
forall p v x q,
L.eq (
get q (
set p v x)) (
if peq q p then v else get q x).
Proof.
Definition eq (
x y:
t) :
Prop :=
forall p,
L.eq (
get p x) (
get p y).
Lemma eq_refl:
forall x,
eq x x.
Proof.
Lemma eq_sym:
forall x y,
eq x y ->
eq y x.
Proof.
Lemma eq_trans:
forall x y z,
eq x y ->
eq y z ->
eq x z.
Proof.
Definition beq (
x y:
t) :
bool :=
PTree.beq L.beq x y.
Lemma beq_correct:
forall x y,
beq x y =
true ->
eq x y.
Proof.
Definition ge (
x y:
t) :
Prop :=
forall p,
L.ge (
get p x) (
get p y).
Lemma ge_refl:
forall x y,
eq x y ->
ge x y.
Proof.
Lemma ge_trans:
forall x y z,
ge x y ->
ge y z ->
ge x z.
Proof.
Definition bot :
t :=
PTree.empty _.
Lemma get_bot:
forall p,
get p bot =
L.bot.
Proof.
Lemma ge_bot:
forall x,
ge x bot.
Proof.
A combine operation over the type PTree.t L.t that attempts
to share its result with its arguments.
Section COMBINE.
Variable f:
option L.t ->
option L.t ->
option L.t.
Hypothesis f_none_none:
f None None =
None.
Definition opt_eq (
ox oy:
option L.t) :
Prop :=
match ox,
oy with
|
None,
None =>
True
|
Some x,
Some y =>
L.eq x y
|
_,
_ =>
False
end.
Lemma opt_eq_refl:
forall ox,
opt_eq ox ox.
Proof.
Lemma opt_eq_sym:
forall ox oy,
opt_eq ox oy ->
opt_eq oy ox.
Proof.
Lemma opt_eq_trans:
forall ox oy oz,
opt_eq ox oy ->
opt_eq oy oz ->
opt_eq ox oz.
Proof.
unfold opt_eq.
destruct ox;
destruct oy;
destruct oz;
intuition.
eapply L.eq_trans;
eauto.
Qed.
Definition opt_beq (
ox oy:
option L.t) :
bool :=
match ox,
oy with
|
None,
None =>
true
|
Some x,
Some y =>
L.beq x y
|
_,
_ =>
false
end.
Lemma opt_beq_correct:
forall ox oy,
opt_beq ox oy =
true ->
opt_eq ox oy.
Proof.
Definition tree_eq (
m1 m2:
PTree.t L.t) :
Prop :=
forall i,
opt_eq (
PTree.get i m1) (
PTree.get i m2).
Lemma tree_eq_refl:
forall m,
tree_eq m m.
Proof.
Lemma tree_eq_sym:
forall m1 m2,
tree_eq m1 m2 ->
tree_eq m2 m1.
Proof.
Lemma tree_eq_trans:
forall m1 m2 m3,
tree_eq m1 m2 ->
tree_eq m2 m3 ->
tree_eq m1 m3.
Proof.
Lemma tree_eq_node:
forall l1 o1 r1 l2 o2 r2,
tree_eq l1 l2 ->
tree_eq r1 r2 ->
opt_eq o1 o2 ->
tree_eq (
PTree.Node l1 o1 r1) (
PTree.Node l2 o2 r2).
Proof.
intros; red; intros. destruct i; simpl; auto.
Qed.
Lemma tree_eq_node':
forall l1 o1 r1 l2 o2 r2,
tree_eq l1 l2 ->
tree_eq r1 r2 ->
opt_eq o1 o2 ->
tree_eq (
PTree.Node l1 o1 r1) (
PTree.Node'
l2 o2 r2).
Proof.
intros;
red;
intros.
rewrite PTree.gnode'.
apply tree_eq_node;
auto.
Qed.
Lemma tree_eq_node'':
forall l1 o1 r1 l2 o2 r2,
tree_eq l1 l2 ->
tree_eq r1 r2 ->
opt_eq o1 o2 ->
tree_eq (
PTree.Node'
l1 o1 r1) (
PTree.Node'
l2 o2 r2).
Proof.
intros;
red;
intros.
repeat rewrite PTree.gnode'.
apply tree_eq_node;
auto.
Qed.
Hint Resolve opt_beq_correct opt_eq_refl opt_eq_sym
tree_eq_refl tree_eq_sym
tree_eq_node tree_eq_node'
tree_eq_node'' :
combine.
Inductive changed:
Type :=
Unchanged |
Changed (
m:
PTree.t L.t).
Fixpoint combine_l (
m :
PTree.t L.t) {
struct m} :
changed :=
match m with
|
PTree.Leaf =>
Unchanged
|
PTree.Node l o r =>
let o' :=
f o None in
match combine_l l,
combine_l r with
|
Unchanged,
Unchanged =>
if opt_beq o'
o then Unchanged else Changed (
PTree.Node'
l o'
r)
|
Unchanged,
Changed r' =>
Changed (
PTree.Node'
l o'
r')
|
Changed l',
Unchanged =>
Changed (
PTree.Node'
l'
o'
r)
|
Changed l',
Changed r' =>
Changed (
PTree.Node'
l'
o'
r')
end
end.
Lemma combine_l_eq:
forall m,
tree_eq (
match combine_l m with Unchanged =>
m |
Changed m' =>
m'
end)
(
PTree.xcombine_l f m).
Proof.
induction m;
simpl.
auto with combine.
destruct (
combine_l m1)
as [ |
l'];
destruct (
combine_l m2)
as [ |
r'];
auto with combine.
case_eq (
opt_beq (
f o None)
o);
auto with combine.
Qed.
Fixpoint combine_r (
m :
PTree.t L.t) {
struct m} :
changed :=
match m with
|
PTree.Leaf =>
Unchanged
|
PTree.Node l o r =>
let o' :=
f None o in
match combine_r l,
combine_r r with
|
Unchanged,
Unchanged =>
if opt_beq o'
o then Unchanged else Changed (
PTree.Node'
l o'
r)
|
Unchanged,
Changed r' =>
Changed (
PTree.Node'
l o'
r')
|
Changed l',
Unchanged =>
Changed (
PTree.Node'
l'
o'
r)
|
Changed l',
Changed r' =>
Changed (
PTree.Node'
l'
o'
r')
end
end.
Lemma combine_r_eq:
forall m,
tree_eq (
match combine_r m with Unchanged =>
m |
Changed m' =>
m'
end)
(
PTree.xcombine_r f m).
Proof.
induction m;
simpl.
auto with combine.
destruct (
combine_r m1)
as [ |
l'];
destruct (
combine_r m2)
as [ |
r'];
auto with combine.
case_eq (
opt_beq (
f None o)
o);
auto with combine.
Qed.
Inductive changed2 :
Type :=
|
Same
|
Same1
|
Same2
|
CC(
m:
PTree.t L.t).
Fixpoint xcombine (
m1 m2 :
PTree.t L.t) {
struct m1} :
changed2 :=
match m1,
m2 with
|
PTree.Leaf,
PTree.Leaf =>
Same
|
PTree.Leaf,
_ =>
match combine_r m2 with
|
Unchanged =>
Same2
|
Changed m =>
CC m
end
|
_,
PTree.Leaf =>
match combine_l m1 with
|
Unchanged =>
Same1
|
Changed m =>
CC m
end
|
PTree.Node l1 o1 r1,
PTree.Node l2 o2 r2 =>
let o :=
f o1 o2 in
match xcombine l1 l2,
xcombine r1 r2 with
|
Same,
Same =>
match opt_beq o o1,
opt_beq o o2 with
|
true,
true =>
Same
|
true,
false =>
Same1
|
false,
true =>
Same2
|
false,
false =>
CC(
PTree.Node'
l1 o r1)
end
|
Same1,
Same |
Same,
Same1 |
Same1,
Same1 =>
if opt_beq o o1 then Same1 else CC(
PTree.Node'
l1 o r1)
|
Same2,
Same |
Same,
Same2 |
Same2,
Same2 =>
if opt_beq o o2 then Same2 else CC(
PTree.Node'
l2 o r2)
|
Same1,
Same2 =>
CC(
PTree.Node'
l1 o r2)
| (
Same|
Same1),
CC r =>
CC(
PTree.Node'
l1 o r)
|
Same2,
Same1 =>
CC(
PTree.Node'
l2 o r1)
|
Same2,
CC r =>
CC(
PTree.Node'
l2 o r)
|
CC l, (
Same|
Same1) =>
CC(
PTree.Node'
l o r1)
|
CC l,
Same2 =>
CC(
PTree.Node'
l o r2)
|
CC l,
CC r =>
CC(
PTree.Node'
l o r)
end
end.
Lemma xcombine_eq:
forall m1 m2,
match xcombine m1 m2 with
|
Same =>
tree_eq m1 (
PTree.combine f m1 m2) /\
tree_eq m2 (
PTree.combine f m1 m2)
|
Same1 =>
tree_eq m1 (
PTree.combine f m1 m2)
|
Same2 =>
tree_eq m2 (
PTree.combine f m1 m2)
|
CC m =>
tree_eq m (
PTree.combine f m1 m2)
end.
Proof.
Definition combine (
m1 m2:
PTree.t L.t) :
PTree.t L.t :=
match xcombine m1 m2 with
|
Same|
Same1 =>
m1
|
Same2 =>
m2
|
CC m =>
m
end.
Lemma gcombine:
forall m1 m2 i,
opt_eq (
PTree.get i (
combine m1 m2)) (
f (
PTree.get i m1) (
PTree.get i m2)).
Proof.
End COMBINE.
Definition lub (
x y:
t) :
t :=
combine
(
fun a b =>
match a,
b with
|
Some u,
Some v =>
Some (
L.lub u v)
|
None,
_ =>
b
|
_,
None =>
a
end)
x y.
Lemma gcombine_bot:
forall f t1 t2 p,
f None None =
None ->
L.eq (
get p (
combine f t1 t2))
(
match f t1!
p t2!
p with Some x =>
x |
None =>
L.bot end).
Proof.
intros.
unfold get.
generalize (
gcombine f H t1 t2 p).
unfold opt_eq.
destruct ((
combine f t1 t2)!
p);
destruct (
f t1!
p t2!
p).
auto.
contradiction.
contradiction.
intros;
apply L.eq_refl.
Qed.
Lemma ge_lub_left:
forall x y,
ge (
lub x y)
x.
Proof.
Lemma ge_lub_right:
forall x y,
ge (
lub x y)
y.
Proof.
End LPMap1.
Given a semi-lattice with top L, the following functor implements
a semi-lattice-with-top structure over finite maps from positive numbers to L.t.
The default value for these maps is L.top. Bottom elements are smashed.
Module LPMap(
L:
SEMILATTICE_WITH_TOP) <:
SEMILATTICE_WITH_TOP.
Inductive t' :
Type :=
|
Bot:
t'
|
Top_except:
PTree.t L.t ->
t'.
Definition t:
Type :=
t'.
Definition get (
p:
positive) (
x:
t) :
L.t :=
match x with
|
Bot =>
L.bot
|
Top_except m =>
match m!
p with None =>
L.top |
Some x =>
x end
end.
Definition set (
p:
positive) (
v:
L.t) (
x:
t) :
t :=
match x with
|
Bot =>
Bot
|
Top_except m =>
if L.beq v L.bot
then Bot
else Top_except (
if L.beq v L.top then PTree.remove p m else PTree.set p v m)
end.
Lemma gsspec:
forall p v x q,
x <>
Bot -> ~
L.eq v L.bot ->
L.eq (
get q (
set p v x)) (
if peq q p then v else get q x).
Proof.
Definition eq (
x y:
t) :
Prop :=
forall p,
L.eq (
get p x) (
get p y).
Lemma eq_refl:
forall x,
eq x x.
Proof.
Lemma eq_sym:
forall x y,
eq x y ->
eq y x.
Proof.
Lemma eq_trans:
forall x y z,
eq x y ->
eq y z ->
eq x z.
Proof.
Definition beq (
x y:
t) :
bool :=
match x,
y with
|
Bot,
Bot =>
true
|
Top_except m,
Top_except n =>
PTree.beq L.beq m n
|
_,
_ =>
false
end.
Lemma beq_correct:
forall x y,
beq x y =
true ->
eq x y.
Proof.
destruct x;
destruct y;
simpl;
intro;
try congruence.
apply eq_refl.
red;
intro;
simpl.
rewrite PTree.beq_correct in H.
generalize (
H p).
destruct (
t0!
p);
destruct (
t1!
p);
intuition.
apply L.beq_correct;
auto.
apply L.eq_refl.
Qed.
Definition ge (
x y:
t) :
Prop :=
forall p,
L.ge (
get p x) (
get p y).
Lemma ge_refl:
forall x y,
eq x y ->
ge x y.
Proof.
Lemma ge_trans:
forall x y z,
ge x y ->
ge y z ->
ge x z.
Proof.
Definition bot :=
Bot.
Lemma get_bot:
forall p,
get p bot =
L.bot.
Proof.
unfold bot;
intros;
simpl.
auto.
Qed.
Lemma ge_bot:
forall x,
ge x bot.
Proof.
Definition top :=
Top_except (
PTree.empty L.t).
Lemma get_top:
forall p,
get p top =
L.top.
Proof.
Lemma ge_top:
forall x,
ge top x.
Proof.
Module LM :=
LPMap1(
L).
Definition opt_lub (
x y:
L.t) :
option L.t :=
let z :=
L.lub x y in
if L.beq z L.top then None else Some z.
Definition lub (
x y:
t) :
t :=
match x,
y with
|
Bot,
_ =>
y
|
_,
Bot =>
x
|
Top_except m,
Top_except n =>
Top_except
(
LM.combine
(
fun a b =>
match a,
b with
|
Some u,
Some v =>
opt_lub u v
|
_,
_ =>
None
end)
m n)
end.
Lemma gcombine_top:
forall f t1 t2 p,
f None None =
None ->
L.eq (
get p (
Top_except (
LM.combine f t1 t2)))
(
match f t1!
p t2!
p with Some x =>
x |
None =>
L.top end).
Proof.
intros.
simpl.
generalize (
LM.gcombine f H t1 t2 p).
unfold LM.opt_eq.
destruct ((
LM.combine f t1 t2)!
p);
destruct (
f t1!
p t2!
p).
auto.
contradiction.
contradiction.
intros;
apply L.eq_refl.
Qed.
Lemma ge_lub_left:
forall x y,
ge (
lub x y)
x.
Proof.
Lemma ge_lub_right:
forall x y,
ge (
lub x y)
y.
Proof.
End LPMap.
Semi-lattice over a set.
Given a set S: FSetInterface.S, the following functor
implements a semi-lattice over these sets, ordered by inclusion.
Module LFSet (
S:
FSetInterface.WS) <:
SEMILATTICE.
Definition t :=
S.t.
Definition eq (
x y:
t) :=
S.Equal x y.
Definition eq_refl:
forall x,
eq x x :=
S.eq_refl.
Definition eq_sym:
forall x y,
eq x y ->
eq y x :=
S.eq_sym.
Definition eq_trans:
forall x y z,
eq x y ->
eq y z ->
eq x z :=
S.eq_trans.
Definition beq:
t ->
t ->
bool :=
S.equal.
Definition beq_correct:
forall x y,
beq x y =
true ->
eq x y :=
S.equal_2.
Definition ge (
x y:
t) :=
S.Subset y x.
Lemma ge_refl:
forall x y,
eq x y ->
ge x y.
Proof.
Lemma ge_trans:
forall x y z,
ge x y ->
ge y z ->
ge x z.
Proof.
Definition bot:
t :=
S.empty.
Lemma ge_bot:
forall x,
ge x bot.
Proof.
Definition lub:
t ->
t ->
t :=
S.union.
Lemma ge_lub_left:
forall x y,
ge (
lub x y)
x.
Proof.
Lemma ge_lub_right:
forall x y,
ge (
lub x y)
y.
Proof.
End LFSet.
Flat semi-lattice
Given a type with decidable equality X, the following functor
returns a semi-lattice structure over X.t complemented with
a top and a bottom element. The ordering is the flat ordering
Bot < Inj x < Top.
Module LFlat(
X:
EQUALITY_TYPE) <:
SEMILATTICE_WITH_TOP.
Inductive t' :
Type :=
|
Bot:
t'
|
Inj:
X.t ->
t'
|
Top:
t'.
Definition t :
Type :=
t'.
Definition eq (
x y:
t) := (
x =
y).
Definition eq_refl:
forall x,
eq x x := (@
refl_equal t).
Definition eq_sym:
forall x y,
eq x y ->
eq y x := (@
sym_equal t).
Definition eq_trans:
forall x y z,
eq x y ->
eq y z ->
eq x z := (@
trans_equal t).
Definition beq (
x y:
t) :
bool :=
match x,
y with
|
Bot,
Bot =>
true
|
Inj u,
Inj v =>
if X.eq u v then true else false
|
Top,
Top =>
true
|
_,
_ =>
false
end.
Lemma beq_correct:
forall x y,
beq x y =
true ->
eq x y.
Proof.
unfold eq;
destruct x;
destruct y;
simpl;
try congruence;
intro.
destruct (
X.eq t0 t1);
congruence.
Qed.
Definition ge (
x y:
t) :
Prop :=
match x,
y with
|
Top,
_ =>
True
|
_,
Bot =>
True
|
Inj a,
Inj b =>
a =
b
|
_,
_ =>
False
end.
Lemma ge_refl:
forall x y,
eq x y ->
ge x y.
Proof.
unfold eq,
ge;
intros;
subst y;
destruct x;
auto.
Qed.
Lemma ge_trans:
forall x y z,
ge x y ->
ge y z ->
ge x z.
Proof.
unfold ge;
destruct x;
destruct y;
try destruct z;
intuition.
transitivity t1;
auto.
Qed.
Definition bot:
t :=
Bot.
Lemma ge_bot:
forall x,
ge x bot.
Proof.
destruct x; simpl; auto.
Qed.
Definition top:
t :=
Top.
Lemma ge_top:
forall x,
ge top x.
Proof.
destruct x; simpl; auto.
Qed.
Definition lub (
x y:
t) :
t :=
match x,
y with
|
Bot,
_ =>
y
|
_,
Bot =>
x
|
Top,
_ =>
Top
|
_,
Top =>
Top
|
Inj a,
Inj b =>
if X.eq a b then Inj a else Top
end.
Lemma ge_lub_left:
forall x y,
ge (
lub x y)
x.
Proof.
destruct x;
destruct y;
simpl;
auto.
case (
X.eq t0 t1);
simpl;
auto.
Qed.
Lemma ge_lub_right:
forall x y,
ge (
lub x y)
y.
Proof.
destruct x;
destruct y;
simpl;
auto.
case (
X.eq t0 t1);
simpl;
auto.
Qed.
End LFlat.
Boolean semi-lattice
This semi-lattice has only two elements, bot and top, trivially
ordered.
Module LBoolean <:
SEMILATTICE_WITH_TOP.
Definition t :=
bool.
Definition eq (
x y:
t) := (
x =
y).
Definition eq_refl:
forall x,
eq x x := (@
refl_equal t).
Definition eq_sym:
forall x y,
eq x y ->
eq y x := (@
sym_equal t).
Definition eq_trans:
forall x y z,
eq x y ->
eq y z ->
eq x z := (@
trans_equal t).
Definition beq :
t ->
t ->
bool :=
eqb.
Lemma beq_correct:
forall x y,
beq x y =
true ->
eq x y.
Proof eqb_prop.
Definition ge (
x y:
t) :
Prop :=
x =
y \/
x =
true.
Lemma ge_refl:
forall x y,
eq x y ->
ge x y.
Proof.
Lemma ge_trans:
forall x y z,
ge x y ->
ge y z ->
ge x z.
Proof.
unfold ge;
intuition congruence. Qed.
Definition bot :=
false.
Lemma ge_bot:
forall x,
ge x bot.
Proof.
destruct x; compute; tauto. Qed.
Definition top :=
true.
Lemma ge_top:
forall x,
ge top x.
Proof.
unfold ge,
top;
tauto. Qed.
Definition lub (
x y:
t) :=
x ||
y.
Lemma ge_lub_left:
forall x y,
ge (
lub x y)
x.
Proof.
destruct x; destruct y; compute; tauto. Qed.
Lemma ge_lub_right:
forall x y,
ge (
lub x y)
y.
Proof.
destruct x; destruct y; compute; tauto. Qed.
End LBoolean.
Option semi-lattice
This lattice adds a top element (represented by None) to a given
semi-lattice (whose elements are injected via Some).
Module LOption(
L:
SEMILATTICE) <:
SEMILATTICE_WITH_TOP.
Definition t:
Type :=
option L.t.
Definition eq (
x y:
t) :
Prop :=
match x,
y with
|
None,
None =>
True
|
Some x1,
Some y1 =>
L.eq x1 y1
|
_,
_ =>
False
end.
Lemma eq_refl:
forall x,
eq x x.
Proof.
unfold eq;
intros;
destruct x.
apply L.eq_refl.
auto.
Qed.
Lemma eq_sym:
forall x y,
eq x y ->
eq y x.
Proof.
unfold eq;
intros;
destruct x;
destruct y;
auto.
apply L.eq_sym;
auto.
Qed.
Lemma eq_trans:
forall x y z,
eq x y ->
eq y z ->
eq x z.
Proof.
unfold eq;
intros;
destruct x;
destruct y;
destruct z;
auto.
eapply L.eq_trans;
eauto.
contradiction.
Qed.
Definition beq (
x y:
t) :
bool :=
match x,
y with
|
None,
None =>
true
|
Some x1,
Some y1 =>
L.beq x1 y1
|
_,
_ =>
false
end.
Lemma beq_correct:
forall x y,
beq x y =
true ->
eq x y.
Proof.
unfold beq,
eq;
intros;
destruct x;
destruct y.
apply L.beq_correct;
auto.
discriminate.
discriminate.
auto.
Qed.
Definition ge (
x y:
t) :
Prop :=
match x,
y with
|
None,
_ =>
True
|
_,
None =>
False
|
Some x1,
Some y1 =>
L.ge x1 y1
end.
Lemma ge_refl:
forall x y,
eq x y ->
ge x y.
Proof.
unfold eq,
ge;
intros;
destruct x;
destruct y.
apply L.ge_refl;
auto.
auto.
elim H.
auto.
Qed.
Lemma ge_trans:
forall x y z,
ge x y ->
ge y z ->
ge x z.
Proof.
unfold ge;
intros;
destruct x;
destruct y;
destruct z;
auto.
eapply L.ge_trans;
eauto.
contradiction.
Qed.
Definition bot :
t :=
Some L.bot.
Lemma ge_bot:
forall x,
ge x bot.
Proof.
Definition lub (
x y:
t) :
t :=
match x,
y with
|
None,
_ =>
None
|
_,
None =>
None
|
Some x1,
Some y1 =>
Some (
L.lub x1 y1)
end.
Lemma ge_lub_left:
forall x y,
ge (
lub x y)
x.
Proof.
Lemma ge_lub_right:
forall x y,
ge (
lub x y)
y.
Proof.
Definition top :
t :=
None.
Lemma ge_top:
forall x,
ge top x.
Proof.
unfold ge,
top;
intros.
auto.
Qed.
End LOption.