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-rw-r--r--AvlVerification.lean18
-rw-r--r--AvlVerification/BinarySearchTree.lean41
-rw-r--r--AvlVerification/Insert.lean95
-rw-r--r--AvlVerification/Specifications.lean62
-rw-r--r--AvlVerification/Tree.lean3
5 files changed, 138 insertions, 81 deletions
diff --git a/AvlVerification.lean b/AvlVerification.lean
index e0516b4..828b2aa 100644
--- a/AvlVerification.lean
+++ b/AvlVerification.lean
@@ -30,7 +30,7 @@ structure AVLTreeSet (T : Type) where
/- [avl_verification::{avl_verification::AVLTreeSet<T>}::new]:
Source: 'src/main.rs', lines 24:4-24:24 -/
def AVLTreeSet.new (T : Type) (OrdInst : Ord T) : Result (AVLTreeSet T) :=
- Result.ret { root := none }
+ Result.ok { root := none }
/- [avl_verification::{avl_verification::AVLTreeSet<T>}::insert]: loop 0:
Source: 'src/main.rs', lines 28:4-46:5 -/
@@ -41,7 +41,7 @@ divergent def AVLTreeSet.insert_loop
:=
match current_tree with
| none => let a := AVLNode.mk value none none
- Result.ret (true, some a)
+ Result.ok (true, some a)
| some current_node =>
do
let ⟨ t, current_tree1, current_tree2 ⟩ := current_node
@@ -50,13 +50,13 @@ divergent def AVLTreeSet.insert_loop
| Ordering.Less =>
do
let (b, back) ← AVLTreeSet.insert_loop T OrdInst value current_tree2
- Result.ret (b, some (AVLNode.mk t current_tree1 back))
+ Result.ok (b, some (AVLNode.mk t current_tree1 back))
| Ordering.Equal =>
- Result.ret (false, some (AVLNode.mk t current_tree1 current_tree2))
+ Result.ok (false, some (AVLNode.mk t current_tree1 current_tree2))
| Ordering.Greater =>
do
let (b, back) ← AVLTreeSet.insert_loop T OrdInst value current_tree1
- Result.ret (b, some (AVLNode.mk t back current_tree2))
+ Result.ok (b, some (AVLNode.mk t back current_tree2))
/- [avl_verification::{avl_verification::AVLTreeSet<T>}::insert]:
Source: 'src/main.rs', lines 28:4-28:46 -/
@@ -66,17 +66,17 @@ def AVLTreeSet.insert
:=
do
let (b, back) ← AVLTreeSet.insert_loop T OrdInst value self.root
- Result.ret (b, { root := back })
+ Result.ok (b, { root := back })
/- [avl_verification::{(avl_verification::Ord for u32)#1}::cmp]:
Source: 'src/main.rs', lines 50:4-50:43 -/
def OrdU32.cmp (self : U32) (other : U32) : Result Ordering :=
if self < other
- then Result.ret Ordering.Less
+ then Result.ok Ordering.Less
else
if self = other
- then Result.ret Ordering.Equal
- else Result.ret Ordering.Greater
+ then Result.ok Ordering.Equal
+ else Result.ok Ordering.Greater
/- Trait implementation: [avl_verification::{(avl_verification::Ord for u32)#1}]
Source: 'src/main.rs', lines 49:0-49:16 -/
diff --git a/AvlVerification/BinarySearchTree.lean b/AvlVerification/BinarySearchTree.lean
index 954f21f..2b17d52 100644
--- a/AvlVerification/BinarySearchTree.lean
+++ b/AvlVerification/BinarySearchTree.lean
@@ -10,34 +10,45 @@ inductive ForallNode (p: T -> Prop): AVLTree T -> Prop
| none : ForallNode p none
| some (a: T) (left: AVLTree T) (right: AVLTree T) : ForallNode p left -> p a -> ForallNode p right -> ForallNode p (some (AVLNode.mk a left right))
-theorem ForallNode.left {p: T -> Prop} {t: AVLTree T}: ForallNode p t -> ForallNode p t.left := sorry
-
-theorem ForallNode.right {p: T -> Prop} {t: AVLTree T}: ForallNode p t -> ForallNode p t.right := sorry
-
-theorem ForallNode.label {a: T} {p: T -> Prop} {left right: AVLTree T}: ForallNode p (AVLNode.mk a left right) -> p a := sorry
+theorem ForallNode.left {p: T -> Prop} {t: AVLTree T}: ForallNode p t -> ForallNode p t.left := by
+ intro Hpt
+ cases Hpt with
+ | none => simp [AVLTree.left, ForallNode.none]
+ | some a left right f_pleft f_pa f_pright => simp [AVLTree.left, f_pleft]
+
+theorem ForallNode.right {p: T -> Prop} {t: AVLTree T}: ForallNode p t -> ForallNode p t.right := by
+ intro Hpt
+ cases Hpt with
+ | none => simp [AVLTree.right, ForallNode.none]
+ | some a left right f_pleft f_pa f_pright => simp [AVLTree.right, f_pright]
+
+theorem ForallNode.label {a: T} {p: T -> Prop} {left right: AVLTree T}: ForallNode p (AVLNode.mk a left right) -> p a := by
+ intro Hpt
+ cases Hpt with
+ | some a left right f_pleft f_pa f_pright => exact f_pa
-- This is the binary search invariant.
-inductive BST [LT T]: AVLTree T -> Prop
-| none : BST none
+inductive Invariant [LT T]: AVLTree T -> Prop
+| none : Invariant none
| some (a: T) (left: AVLTree T) (right: AVLTree T) :
ForallNode (fun v => v < a) left -> ForallNode (fun v => a < v) right
- -> BST left -> BST right -> BST (some (AVLNode.mk a left right))
+ -> Invariant left -> Invariant right -> Invariant (some (AVLNode.mk a left right))
@[simp]
-theorem singleton_bst [LT T] {a: T}: BST (some (AVLNode.mk a none none)) := by
- apply BST.some
- all_goals simp [ForallNode.none, BST.none]
+theorem singleton_bst [LT T] {a: T}: Invariant (some (AVLNode.mk a none none)) := by
+ apply Invariant.some
+ all_goals simp [ForallNode.none, Invariant.none]
-theorem left [LT T] {t: AVLTree T}: BST t -> BST t.left := by
+theorem left [LT T] {t: AVLTree T}: Invariant t -> Invariant t.left := by
intro H
induction H with
- | none => exact BST.none
+ | none => exact Invariant.none
| some _ _ _ _ _ _ _ _ _ => simp [AVLTree.left]; assumption
-theorem right [LT T] {t: AVLTree T}: BST t -> BST t.right := by
+theorem right [LT T] {t: AVLTree T}: Invariant t -> Invariant t.right := by
intro H
induction H with
- | none => exact BST.none
+ | none => exact Invariant.none
| some _ _ _ _ _ _ _ _ _ => simp [AVLTree.right]; assumption
end BST
diff --git a/AvlVerification/Insert.lean b/AvlVerification/Insert.lean
index 3c2b8b3..baf3441 100644
--- a/AvlVerification/Insert.lean
+++ b/AvlVerification/Insert.lean
@@ -7,9 +7,47 @@ namespace Implementation
open Primitives
open avl_verification
open Tree (AVLTree)
-open Specifications (OrdSpec ordSpecOfInfaillible ordOfOrdSpec ltOfRustOrder)
+open Specifications (OrdSpec ordSpecOfTotalityAndDuality ordOfOrdSpec ltOfRustOrder gtOfRustOrder)
+
+example: OrdSpec OrdU32 := ordSpecOfTotalityAndDuality _
+ (by
+ -- Totality
+ intro a b
+ unfold Ord.cmp
+ unfold OrdU32
+ unfold OrdU32.cmp
+ if hlt : a < b then
+ use .Less
+ simp [hlt]
+ else
+ if heq: a = b
+ then
+ use .Equal
+ simp [hlt]
+ rw [heq]
+ -- TODO: simp [hlt, heq] breaks everything???
+ else
+ use .Greater
+ simp [hlt, heq]
+ ) (by
+ -- Duality
+ intro a b Hgt
+ if hlt : b < a then
+ unfold Ord.cmp
+ unfold OrdU32
+ unfold OrdU32.cmp
+ simp [hlt]
+ else
+ unfold Ord.cmp at Hgt
+ unfold OrdU32 at Hgt
+ unfold OrdU32.cmp at Hgt
+ have hnlt : ¬ (a < b) := sorry
+ have hneq : ¬ (a = b) := sorry
+ exfalso
+ apply hlt
+ -- I need a Preorder on U32 now.
+ sorry)
--- TODO: OSpec should be proven.
variable (T: Type) (H: avl_verification.Ord T) (Ospec: @OrdSpec T H)
instance rustOrder {U: Type} {O: avl_verification.Ord U} (OSpec: OrdSpec O): _root_.Ord U := ordOfOrdSpec O OSpec
@@ -20,9 +58,9 @@ instance rustLt' : LT T := rustLt Ospec
@[pspec]
theorem AVLTreeSet.insert_loop_spec_local (p: T -> Prop)
- (Hcmp_spec: ∀ a b, ∃ o, H.cmp a b = Result.ret o)
+ (Hcmp_spec: ∀ a b, ∃ o, H.cmp a b = Result.ok o)
(a: T) (t: Option (AVLNode T)):
- ∃ added t_new, AVLTreeSet.insert_loop T H a t = Result.ret ⟨ added, t_new ⟩
+ ∃ added t_new, AVLTreeSet.insert_loop T H a t = Result.ok ⟨ added, t_new ⟩
-- ∧ AVLTree.set t'.2 = insert a (AVLTree.set t)
∧ (BST.ForallNode p t -> p a -> BST.ForallNode p t_new)
:= by match t with
@@ -68,8 +106,8 @@ lemma AVLTreeSet.insert_loop_spec_global
(a: T) (t: Option (AVLNode T))
:
haveI : LT T := (rustLt Ospec)
- BST.BST t -> ∃ added t_new, AVLTreeSet.insert_loop T H a t = Result.ret ⟨ added, t_new ⟩
- ∧ BST.BST t_new := by
+ BST.Invariant t -> ∃ added t_new, AVLTreeSet.insert_loop T H a t = Result.ok ⟨ added, t_new ⟩
+ ∧ BST.Invariant t_new := by
intro Hbst
letI instOrd : _root_.Ord T := (rustOrder Ospec)
letI instLt : LT T := (rustLt Ospec)
@@ -78,9 +116,7 @@ lemma AVLTreeSet.insert_loop_spec_global
| some (AVLNode.mk b left right) =>
rw [AVLTreeSet.insert_loop]
simp only []
- have := Ospec.infallible; simp at this
- -- TODO: unbundle `this`...
- have : ∀ a b, ∃ o, H.cmp a b = .ret o := sorry
+ have : ∀ a b, ∃ o, H.cmp a b = .ok o := Ospec.infallible
progress keep Hordering as ⟨ ordering ⟩
cases ordering
all_goals simp only []
@@ -104,34 +140,33 @@ lemma AVLTreeSet.insert_loop_spec_global
simp; tauto
}
{
- sorry
+ have ⟨ added₂, left₂, ⟨ H_result, H_bst ⟩ ⟩ := AVLTreeSet.insert_loop_spec_global a left (BST.left Hbst)
+ progress keep Htree with AVLTreeSet.insert_loop_spec_local as ⟨ added₁, left₁, Hnode ⟩
+ exact (fun x => x < b)
+ rewrite [Htree] at H_result; simp at H_result
+ refine' ⟨ added₁, ⟨ some (AVLNode.mk b left₁ right), _ ⟩ ⟩
+ simp only [true_and]
+ cases' Hbst with _ _ _ H_forall_left H_forall_right H_bst_left H_bst_right
+ constructor
+ apply Hnode; exact H_forall_left
+ exact (gtOfRustOrder H b a Hordering)
+ exact H_forall_right
+ convert H_bst
+ exact H_result.2
+ exact H_bst_right
}
@[pspec]
def AVLTreeSet.insert_spec
- {H: avl_verification.Ord T}
- -- TODO: this can be generalized into `H.cmp` must be an equivalence relation.
- -- and insert works no longer on Sets but on set quotiented by this equivalence relation.
- (Hcmp_eq: ∀ a b, H.cmp a b = Result.ret Ordering.Equal -> a = b)
- (Hcmp_spec: ∀ a b, ∃ o, H.cmp a b = Result.ret o)
- (Hbs_search: @BSTree.searchInvariant _ H t)
(a: T) (t: AVLTreeSet T):
- ∃ t', t.insert _ H a = Result.ret t'
- -- set of values *POST* insertion is {a} \cup set of values of the *PRE* tree.
- ∧ AVLTree.setOf t'.2.root = insert a (AVLTree.setOf t.root)
+ haveI : LT T := (rustLt Ospec)
+ BST.Invariant t.root -> (∃ t' added,t.insert _ H a = Result.ok (added, t')
-- it's still a binary search tree.
- ∧ @BSTree.searchInvariant _ H t'.2.root
- -- TODO(reinforcement): (t'.1 is false <=> a \in AVLTree.setOf t.root)
+ ∧ BST.Invariant t'.root)
:= by
- rw [AVLTreeSet.insert]
- progress keep h as ⟨ t', Hset ⟩; simp
- rw [Hset]
- sorry
-
-
--- insert is infaillible, right?
--- instance [LT T] (o: avl_verification.Ord T): Insert T (AVLTreeSet T) where
--- insert x tree := (AVLTreeSet.insert T o tree x).map (fun (added, tree) => tree)
+ rw [AVLTreeSet.insert]; intro Hbst
+ progress keep h as ⟨ t', Hset ⟩;
+ simp; assumption
end Implementation
diff --git a/AvlVerification/Specifications.lean b/AvlVerification/Specifications.lean
index 247fd00..958a3e7 100644
--- a/AvlVerification/Specifications.lean
+++ b/AvlVerification/Specifications.lean
@@ -5,19 +5,19 @@ namespace Primitives
namespace Result
def map {A B: Type} (x: Result A) (f: A -> B): Result B := match x with
-| .ret y => .ret (f y)
+| .ok y => .ok (f y)
| .fail e => .fail e
| .div => .div
@[inline]
-def isRet {A: Type} : Result A -> Bool
-| .ret _ => true
+def isok {A: Type} : Result A -> Bool
+| .ok _ => true
| .fail _ => false
| .div => false
@[inline]
-def get? {A: Type}: (r: Result A) -> isRet r -> A
-| .ret x, _ => x
+def get? {A: Type}: (r: Result A) -> isok r -> A
+| .ok x, _ => x
end Result
@@ -30,6 +30,11 @@ def Ordering.toLeanOrdering (o: avl_verification.Ordering): _root_.Ordering := m
| .Equal => .eq
| .Greater => .gt
+def Ordering.ofLeanOrdering (o: _root_.Ordering): avl_verification.Ordering := match o with
+| .lt => .Less
+| .eq => .Equal
+| .gt => .Greater
+
end avl_verification
namespace Specifications
@@ -39,42 +44,51 @@ open Result
variable {T: Type} (H: avl_verification.Ord T)
+-- TODO: reason about raw bundling vs. refined bundling.
class OrdSpec where
- cmp: T -> T -> Result Ordering := fun x y => (H.cmp x y).map (fun z => z.toLeanOrdering)
- infallible: ∀ a b, ∃ (o: Ordering), cmp a b = .ret o
-
-@[simp]
-theorem OrdSpec.cmpEq {Spec: OrdSpec H}: ∀ x y, Spec.cmp x y = (H.cmp x y).map (fun z => z.toLeanOrdering) := sorry
-
-@[simp]
-theorem OrdSpec.infallibleEq {Spec: OrdSpec H}: ∀ a b, ∃ (o: Ordering), Spec.cmp a b = .ret o <-> ∀ a b, ∃ (o: Ordering), (H.cmp a b).map (fun z => z.toLeanOrdering) = .ret o := sorry
+ infallible: ∀ a b, ∃ (o: avl_verification.Ordering), H.cmp a b = .ok o
+ duality: ∀ a b, H.cmp a b = .ok .Greater -> H.cmp b a = .ok .Less
instance: Coe (avl_verification.Ordering) (_root_.Ordering) where
coe a := a.toLeanOrdering
-def ordSpecOfInfaillible
+def ordSpecOfTotalityAndDuality
(H: avl_verification.Ord T)
- (Hresult: ∀ a b, ∃ o, H.cmp a b = Primitives.Result.ret o)
+ (Hresult: ∀ a b, ∃ o, H.cmp a b = Primitives.Result.ok o)
+ (Hduality: ∀ a b, H.cmp a b = .ok .Greater -> H.cmp b a = .ok .Less)
: OrdSpec H where
- infallible := by
- intros a b; cases' (Hresult a b) with o Hcmp; refine' ⟨ o.toLeanOrdering, _ ⟩
- simp [Result.map, Hcmp]
+ infallible := Hresult
+ duality := Hduality
def ordOfOrdSpec (H: avl_verification.Ord T) (spec: OrdSpec H): Ord T where
- compare x y := (spec.cmp x y).get? (by
+ compare x y := (H.cmp x y).get? (by
cases' (spec.infallible x y) with o Hcmp
- rewrite [isRet, Hcmp]
+ rewrite [isok, Hcmp]
simp only
)
theorem ltOfRustOrder {Spec: OrdSpec H}:
haveI O := ordOfOrdSpec H Spec
haveI := @ltOfOrd _ O
- ∀ a b, H.cmp a b = .ret .Less -> a < b := by
+ ∀ a b, H.cmp a b = .ok .Less -> a < b := by
intros a b
intro Hcmp
- change ((Spec.cmp a b).get? _ == .lt)
- simp [Hcmp, map, avl_verification.Ordering.toLeanOrdering]
- simp [get?]
+ rw [LT.lt]
+ simp [ltOfOrd]
+ rw [compare]
+ simp [ordOfOrdSpec]
+ -- https://proofassistants.stackexchange.com/questions/1062/what-does-the-motive-is-not-type-correct-error-mean-in-lean
+ simp_rw [Hcmp, get?, avl_verification.Ordering.toLeanOrdering]
rfl
+
+theorem gtOfRustOrder {Spec: OrdSpec H}:
+ haveI O := ordOfOrdSpec H Spec
+ haveI := @ltOfOrd _ O
+ ∀ a b, H.cmp a b = .ok .Greater -> b < a := by
+ intros a b
+ intro Hcmp
+ apply ltOfRustOrder
+ exact (Spec.duality _ _ Hcmp)
+
+
end Specifications
diff --git a/AvlVerification/Tree.lean b/AvlVerification/Tree.lean
index 3316e9e..fdd4b78 100644
--- a/AvlVerification/Tree.lean
+++ b/AvlVerification/Tree.lean
@@ -75,7 +75,4 @@ def AVLTree.mem_some {x: T} {left right: AVLTree T}: AVLTree.mem (some (AVLNode.
def AVLTree.set (t: AVLTree T): Set T := _root_.setOf (AVLTree.mem t)
-def AVLTree.setOf_left_incl (t: AVLTree T): t.left.set ⊂ t.set := sorry
-def AVLTree.setOf_right_incl (t: AVLTree T): t.right.set ⊂ t.set := sorry
-
end Tree