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Author SHA1 Message Date
332b7616cf Prove that foldr is monotonic when input lists are pairwise monotonic
This should help prove that "join" is monotonic

Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
2024-03-07 21:53:45 -08:00
7905d106e2 Tweak signature of 'forget' to simplify proofs
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
2024-03-07 20:04:33 -08:00
34203840c8 Use the new provenance function to clean up some proofs
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
2024-03-07 19:59:14 -08:00
4 changed files with 123 additions and 118 deletions

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@ -85,6 +85,20 @@ record IsSemilattice {a} (A : Set a)
≼-refl : (a : A) a a ≼-refl : (a : A) a a
≼-refl a = ⊔-idemp a ≼-refl a = ⊔-idemp a
≼-trans : {a₁ a₂ a₃ : A} a₁ a₂ a₂ a₃ a₁ a₃
≼-trans {a₁} {a₂} {a₃} a₁≼a₂ a₂≼a₃ =
begin
a₁ a₃
∼⟨ ≈-⊔-cong ≈-refl (≈-sym a₂≼a₃)
a₁ (a₂ a₃)
∼⟨ ≈-sym (⊔-assoc _ _ _)
(a₁ a₂) a₃
∼⟨ ≈-⊔-cong a₁≼a₂ ≈-refl
a₂ a₃
∼⟨ a₂≼a₃
a₃
≼-cong : {a₁ a₂ a₃ a₄ : A} a₁ a₂ a₃ a₄ a₁ a₃ a₂ a₄ ≼-cong : {a₁ a₂ a₃ a₄ : A} a₁ a₂ a₃ a₄ a₁ a₃ a₂ a₄
≼-cong {a₁} {a₂} {a₃} {a₄} a₁≈a₂ a₃≈a₄ a₁⊔a₃≈a₃ = ≼-cong {a₁} {a₂} {a₃} {a₄} a₁≈a₂ a₃≈a₄ a₁⊔a₃≈a₃ =
begin begin
@ -118,11 +132,24 @@ module _ {a b} {A : Set a} {B : Set b}
(lA : IsSemilattice A _≈₁_ _⊔₁_) (lB : IsSemilattice B _≈₂_ _⊔₂_) where (lA : IsSemilattice A _≈₁_ _⊔₁_) (lB : IsSemilattice B _≈₂_ _⊔₂_) where
open IsSemilattice lA using () renaming (_≼_ to _≼₁_) open IsSemilattice lA using () renaming (_≼_ to _≼₁_)
open IsSemilattice lB using () renaming (_≼_ to _≼₂_; ⊔-idemp to ⊔₂-idemp) open IsSemilattice lB using () renaming (_≼_ to _≼₂_; ⊔-idemp to ⊔₂-idemp; ≼-trans to ≼₂-trans)
const-Mono : (x : B) Monotonic _≼₁_ _≼₂_ (λ _ x) const-Mono : (x : B) Monotonic _≼₁_ _≼₂_ (λ _ x)
const-Mono x _ = ⊔₂-idemp x const-Mono x _ = ⊔₂-idemp x
open import Data.List as List using (List; foldr; _∷_)
open import Utils using (Pairwise; _∷_)
foldr-Mono : (l₁ l₂ : List A) (f : A B B) (b₁ b₂ : B)
Pairwise _≼₁_ l₁ l₂ b₁ ≼₂ b₂
( b Monotonic _≼₁_ _≼₂_ (λ a f a b))
( a Monotonic _≼₂_ _≼₂_ (f a))
foldr f b₁ l₁ ≼₂ foldr f b₂ l₂
foldr-Mono List.[] List.[] f b₁ b₂ _ b₁≼b₂ _ _ = b₁≼b₂
foldr-Mono (x xs) (y ys) f b₁ b₂ (x≼y xs≼ys) b₁≼b₂ f-Mono₁ f-Mono₂ =
≼₂-trans (f-Mono₁ (foldr f b₁ xs) x≼y)
(f-Mono₂ y (foldr-Mono xs ys f b₁ b₂ xs≼ys b₁≼b₂ f-Mono₁ f-Mono₂))
record IsLattice {a} (A : Set a) record IsLattice {a} (A : Set a)
(_≈_ : A A Set a) (_≈_ : A A Set a)
(_⊔_ : A A A) (_⊔_ : A A A)
@ -146,6 +173,7 @@ record IsLattice {a} (A : Set a)
; _≼_ to _≽_ ; _≼_ to _≽_
; _≺_ to _≻_ ; _≺_ to _≻_
; ≼-refl to ≽-refl ; ≼-refl to ≽-refl
; ≼-trans to ≽-trans
) )
FixedHeight : (h : ) Set a FixedHeight : (h : ) Set a

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@ -36,6 +36,7 @@ open import Lattice.Map A B _≈₂_ _⊔₂_ _⊓₂_ ≡-dec-A lB
; _∈_ ; _∈_
; Map-functional ; Map-functional
; Expr-Provenance ; Expr-Provenance
; Expr-Provenance-≡
; _∩_; __; `_ ; _∩_; __; `_
; in₁; in₂; bothᵘ; single ; in₁; in₂; bothᵘ; single
; ⊔-combines ; ⊔-combines
@ -184,7 +185,7 @@ module IterProdIsomorphism where
narrow₂ {fm₁} {fm₂ = (_ fm'₂ , push k≢ks _) , kvs≡ks@refl} kvs₁⊆kvs₂ k' v' k',v'∈fm'₁ narrow₂ {fm₁} {fm₂ = (_ fm'₂ , push k≢ks _) , kvs≡ks@refl} kvs₁⊆kvs₂ k' v' k',v'∈fm'₁
with kvs₁⊆kvs₂ k' v' k',v'∈fm'₁ with kvs₁⊆kvs₂ k' v' k',v'∈fm'₁
... | (v'' , (v'≈v'' , here refl)) rewrite sym (proj₂ fm₁) = ... | (v'' , (v'≈v'' , here refl)) rewrite sym (proj₂ fm₁) =
⊥-elim (All¬-¬Any k≢ks (forget {m = proj₁ fm₁} k',v'∈fm'₁)) ⊥-elim (All¬-¬Any k≢ks (forget k',v'∈fm'₁))
... | (v'' , (v'≈v'' , there k',v'∈fm'₂)) = ... | (v'' , (v'≈v'' , there k',v'∈fm'₂)) =
(v'' , (v'≈v'' , k',v'∈fm'₂)) (v'' , (v'≈v'' , k',v'∈fm'₂))
@ -195,7 +196,7 @@ module IterProdIsomorphism where
k,v∈pop⇒k,v∈ : {k : A} {ks : List A} {k' : A} {v : B} (fm : FiniteMap (k ks)) k,v∈pop⇒k,v∈ : {k : A} {ks : List A} {k' : A} {v : B} (fm : FiniteMap (k ks))
(k' , v) ∈ᵐ pop fm (¬ k k' × ((k' , v) ∈ᵐ fm)) (k' , v) ∈ᵐ pop fm (¬ k k' × ((k' , v) ∈ᵐ fm))
k,v∈pop⇒k,v∈ {k} {ks} {k'} {v} (m@((k , _) fm' , push k≢ks uks') , refl) k',v∈fm = k,v∈pop⇒k,v∈ {k} {ks} {k'} {v} (m@((k , _) fm' , push k≢ks uks') , refl) k',v∈fm =
( (λ { refl All¬-¬Any k≢ks (forget {m = (fm' , uks')} k',v∈fm) }) ( (λ { refl All¬-¬Any k≢ks (forget k',v∈fm) })
, there k',v∈fm , there k',v∈fm
) )
@ -212,17 +213,16 @@ module IterProdIsomorphism where
Provenance-union : {ks : List A} (fm₁ fm₂ : FiniteMap ks) {k : A} {v : B} Provenance-union : {ks : List A} (fm₁ fm₂ : FiniteMap ks) {k : A} {v : B}
(k , v) ∈ᵐ (fm₁ ⊔ᵐ fm₂) FromBothMaps k v fm₁ fm₂ (k , v) ∈ᵐ (fm₁ ⊔ᵐ fm₂) FromBothMaps k v fm₁ fm₂
Provenance-union fm₁@(m₁ , ks₁≡ks) fm₂@(m₂ , ks₂≡ks) {k} {v} k,v∈fm₁fm₂ Provenance-union fm₁@(m₁ , ks₁≡ks) fm₂@(m₂ , ks₂≡ks) {k} {v} k,v∈fm₁fm₂
with Expr-Provenance k ((` m₁) (` m₂)) (forget {m = proj₁ (fm₁ ⊔ᵐ fm₂)} k,v∈fm₁fm₂) with Expr-Provenance-≡ ((` m₁) (` m₂)) k,v∈fm₁fm₂
... | (_ , (in (single k,v∈m₁) k∉km₂ , _)) ... | in (single k,v∈m₁) k∉km₂
with k∈km₁ (forget {m = m₁} k,v∈m₁) with k∈km₁ (forget k,v∈m₁)
rewrite trans ks₁≡ks (sym ks₂≡ks) = rewrite trans ks₁≡ks (sym ks₂≡ks) =
⊥-elim (k∉km₂ k∈km₁) ⊥-elim (k∉km₂ k∈km₁)
... | (_ , (in k∉km₁ (single k,v∈m₂) , _)) ... | in k∉km₁ (single k,v∈m₂)
with k∈km₂ (forget {m = m₂} k,v∈m₂) with k∈km₂ (forget k,v∈m₂)
rewrite trans ks₁≡ks (sym ks₂≡ks) = rewrite trans ks₁≡ks (sym ks₂≡ks) =
⊥-elim (k∉km₁ k∈km₂) ⊥-elim (k∉km₁ k∈km₂)
... | (v₁⊔v₂ , (bothᵘ {v₁} {v₂} (single k,v₁∈m₁) (single k,v₂∈m₂) , k,v₁⊔v₂∈m₁m₂)) ... | bothᵘ {v₁} {v₂} (single k,v₁∈m₁) (single k,v₂∈m₂) =
rewrite Map-functional {m = proj₁ (fm₁ ⊔ᵐ fm₂)} k,v∈fm₁fm₂ k,v₁⊔v₂∈m₁m₂ =
((v₁ , v₂) , (refl , (k,v₁∈m₁ , k,v₂∈m₂))) ((v₁ , v₂) , (refl , (k,v₁∈m₁ , k,v₂∈m₂)))
pop-⊔-distr : {k : A} {ks : List A} (fm₁ fm₂ : FiniteMap (k ks)) pop-⊔-distr : {k : A} {ks : List A} (fm₁ fm₂ : FiniteMap (k ks))
@ -324,11 +324,9 @@ module IterProdIsomorphism where
| from-first-value (fm₁ ⊔ᵐ fm₂) | from-first-value (fm₁ ⊔ᵐ fm₂)
| from-first-value fm₁ | from-first-value fm₂ | from-first-value fm₁ | from-first-value fm₂
... | (v , k,v∈fm₁fm₂) | (v₁ , k,v₁∈fm₁) | (v₂ , k,v₂∈fm₂) | refl | refl | refl ... | (v , k,v∈fm₁fm₂) | (v₁ , k,v₁∈fm₁) | (v₂ , k,v₂∈fm₂) | refl | refl | refl
with Expr-Provenance k ((` m₁) (` m₂)) (forget {m = proj₁ (fm₁ ⊔ᵐ fm₂)} k,v∈fm₁fm₂) with Expr-Provenance k ((` m₁) (` m₂)) (forget k,v∈fm₁fm₂)
... | (_ , (in _ k∉km₂ , _)) = ⊥-elim (k∉km₂ (forget {m = m₂} ... | (_ , (in _ k∉km₂ , _)) = ⊥-elim (k∉km₂ (forget k,v₂∈fm₂))
k,v₂∈fm₂)) ... | (_ , (in k∉km₁ _ , _)) = ⊥-elim (k∉km₁ (forget k,v₁∈fm₁))
... | (_ , (in k∉km₁ _ , _)) = ⊥-elim (k∉km₁ (forget {m = m₁}
k,v₁∈fm₁))
... | (v₁⊔v₂ , (bothᵘ {v₁'} {v₂'} (single k,v₁'∈m₁) (single k,v₂'∈m₂) , k,v₁⊔v₂∈m₁m₂)) ... | (v₁⊔v₂ , (bothᵘ {v₁'} {v₂'} (single k,v₁'∈m₁) (single k,v₂'∈m₂) , k,v₁⊔v₂∈m₁m₂))
rewrite Map-functional {m = m₁} k,v₁∈fm₁ k,v₁'∈m₁ rewrite Map-functional {m = m₁} k,v₁∈fm₁ k,v₁'∈m₁
rewrite Map-functional {m = m₂} k,v₂∈fm₂ k,v₂'∈m₂ rewrite Map-functional {m = m₂} k,v₂∈fm₂ k,v₂'∈m₂
@ -387,10 +385,10 @@ module IterProdIsomorphism where
(v , (IsLattice.≈-refl lB , here refl)) (v , (IsLattice.≈-refl lB , here refl))
... | here refl | there k',v₂∈fm₂' = ... | here refl | there k',v₂∈fm₂' =
⊥-elim (All¬-¬Any k≢ks' (subst (k' ∈ˡ_) (proj₂ fm₂') ⊥-elim (All¬-¬Any k≢ks' (subst (k' ∈ˡ_) (proj₂ fm₂')
(forget {m = proj₁ fm₂'} k',v₂∈fm₂'))) (forget k',v₂∈fm₂')))
... | there k',v₁∈fm₁' | here refl = ... | there k',v₁∈fm₁' | here refl =
⊥-elim (All¬-¬Any k≢ks' (subst (k' ∈ˡ_) (proj₂ fm₁') ⊥-elim (All¬-¬Any k≢ks' (subst (k' ∈ˡ_) (proj₂ fm₁')
(forget {m = proj₁ fm₁'} k',v₁∈fm₁'))) (forget k',v₁∈fm₁')))
... | there k',v₁∈fm₁' | there k',v₂∈fm₂' = ... | there k',v₁∈fm₁' | there k',v₂∈fm₂' =
let let
k',v₁v₂∈fm₁'fm₂' = k',v₁v₂∈fm₁'fm₂' =

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@ -488,7 +488,9 @@ _∈k_ k m = MemProp._∈_ k (keys m)
locate : {k : A} {m : Map} k ∈k m Σ B (λ v (k , v) m) locate : {k : A} {m : Map} k ∈k m Σ B (λ v (k , v) m)
locate k∈km = locate-impl k∈km locate k∈km = locate-impl k∈km
forget : {k : A} {v : B} {m : Map} (k , v) m k ∈k m -- defined this way because ∈ for maps uses projection, so the full map can't be guessed.
-- On the other hand, list can be guessed.
forget : {k : A} {v : B} {l : List (A × B)} (k , v) ∈ˡ l k ∈ˡ (ImplKeys.keys l)
forget = ∈-cong proj₁ forget = ∈-cong proj₁
Map-functional : {k : A} {v v' : B} {m : Map} (k , v) m (k , v') m v v' Map-functional : {k : A} {v v' : B} {m : Map} (k , v) m (k , v') m v v'
@ -592,9 +594,9 @@ Expr-Provenance k (e₁ ∩ e₂) k∈ke₁e₂
... | no k∉ke₁ | yes k∈ke₂ = ⊥-elim (intersect-preserves-∉₁ {l₂ = proj₁ e₂ } k∉ke₁ k∈ke₁e₂) ... | no k∉ke₁ | yes k∈ke₂ = ⊥-elim (intersect-preserves-∉₁ {l₂ = proj₁ e₂ } k∉ke₁ k∈ke₁e₂)
... | no k∉ke₁ | no k∉ke₂ = ⊥-elim (intersect-preserves-∉₂ {l₁ = proj₁ e₁ } k∉ke₂ k∈ke₁e₂) ... | no k∉ke₁ | no k∉ke₂ = ⊥-elim (intersect-preserves-∉₂ {l₁ = proj₁ e₁ } k∉ke₂ k∈ke₁e₂)
Expr-Provenance-≡ : (k : A) (v : B) (e : Expr) (k , v) e Provenance k v e Expr-Provenance-≡ : {k : A} {v : B} (e : Expr) (k , v) e Provenance k v e
Expr-Provenance-≡ k v e k,v∈e Expr-Provenance-≡ {k} {v} e k,v∈e
with (v' , (p , k,v'∈e)) Expr-Provenance k e (forget {m = e } k,v∈e) with (v' , (p , k,v'∈e)) Expr-Provenance k e (forget k,v∈e)
rewrite Map-functional {m = e } k,v∈e k,v'∈e = p rewrite Map-functional {m = e } k,v∈e k,v'∈e = p
module _ (≈₂-dec : IsDecidable _≈₂_) where module _ (≈₂-dec : IsDecidable _≈₂_) where
@ -609,7 +611,7 @@ module _ (≈₂-dec : IsDecidable _≈₂_) where
let (v , k,v∈m₁) = locate-impl k∈km₁ let (v , k,v∈m₁) = locate-impl k∈km₁
in no (λ m₁⊆m₂ in no (λ m₁⊆m₂
let (v' , (_ , k,v'∈m₂)) = m₁⊆m₂ k v k,v∈m₁ let (v' , (_ , k,v'∈m₂)) = m₁⊆m₂ k v k,v∈m₁
in k∉km₂ (∈-cong proj₁ k,v'∈m₂)) in k∉km₂ (forget k,v'∈m₂))
SubsetInfo-to-dec {m₁} {m₂} (mismatch k v₁ v₂ k,v₁∈m₁ k,v₂∈m₂ v₁̷≈v₂) = SubsetInfo-to-dec {m₁} {m₂} (mismatch k v₁ v₂ k,v₁∈m₁ k,v₂∈m₂ v₁̷≈v₂) =
no (λ m₁⊆m₂ no (λ m₁⊆m₂
let (v' , (v₁≈v' , k,v'∈m₂)) = m₁⊆m₂ k v₁ k,v₁∈m₁ let (v' , (v₁≈v' , k,v'∈m₂)) = m₁⊆m₂ k v₁ k,v₁∈m₁
@ -665,19 +667,16 @@ private module I⊓ = ImplInsert _⊓₂_
⊔-⊆ : (m₁ m₂ m₃ m₄ : Map) m₁ m₂ m₃ m₄ (m₁ m₃) (m₂ m₄) ⊔-⊆ : (m₁ m₂ m₃ m₄ : Map) m₁ m₂ m₃ m₄ (m₁ m₃) (m₂ m₄)
⊔-⊆ m₁ m₂ m₃ m₄ m₁≈m₂ m₃≈m₄ k v k,v∈m₁m₃ ⊔-⊆ m₁ m₂ m₃ m₄ m₁≈m₂ m₃≈m₄ k v k,v∈m₁m₃
with Expr-Provenance k ((` m₁) (` m₃)) (∈-cong proj₁ k,v∈m₁m₃) with Expr-Provenance-≡ ((` m₁) (` m₃)) k,v∈m₁m₃
... | (_ , (bothᵘ (single {v₁} v₁∈m₁) (single {v₃} v₃∈m₃) , v₁v₃∈m₁m₃)) ... | bothᵘ (single {v₁} v₁∈m₁) (single {v₃} v₃∈m₃) =
rewrite Map-functional {m = m₁ m₃} k,v∈m₁m₃ v₁v₃∈m₁m₃ =
let (v₂ , (v₁≈v₂ , k,v₂∈m₂)) = proj₁ m₁≈m₂ k v₁ v₁∈m₁ let (v₂ , (v₁≈v₂ , k,v₂∈m₂)) = proj₁ m₁≈m₂ k v₁ v₁∈m₁
(v₄ , (v₃≈v₄ , k,v₄∈m₄)) = proj₁ m₃≈m₄ k v₃ v₃∈m₃ (v₄ , (v₃≈v₄ , k,v₄∈m₄)) = proj₁ m₃≈m₄ k v₃ v₃∈m₃
in (v₂ ⊔₂ v₄ , (≈₂-⊔₂-cong v₁≈v₂ v₃≈v₄ , I⊔.union-combines (proj₂ m₂) (proj₂ m₄) k,v₂∈m₂ k,v₄∈m₄)) in (v₂ ⊔₂ v₄ , (≈₂-⊔₂-cong v₁≈v₂ v₃≈v₄ , I⊔.union-combines (proj₂ m₂) (proj₂ m₄) k,v₂∈m₂ k,v₄∈m₄))
... | (_ , (in (single {v₁} v₁∈m₁) k∉km₃ , v₁∈m₁m₃)) ... | in (single {v₁} v₁∈m₁) k∉km₃ =
rewrite Map-functional {m = m₁ m₃} k,v∈m₁m₃ v₁∈m₁m₃ =
let (v₂ , (v₁≈v₂ , k,v₂∈m₂)) = proj₁ m₁≈m₂ k v₁ v₁∈m₁ let (v₂ , (v₁≈v₂ , k,v₂∈m₂)) = proj₁ m₁≈m₂ k v₁ v₁∈m₁
k∉km₄ = ≈-∉-cong {m₃} {m₄} m₃≈m₄ k∉km₃ k∉km₄ = ≈-∉-cong {m₃} {m₄} m₃≈m₄ k∉km₃
in (v₂ , (v₁≈v₂ , I⊔.union-preserves-∈₁ (proj₂ m₂) k,v₂∈m₂ k∉km₄)) in (v₂ , (v₁≈v₂ , I⊔.union-preserves-∈₁ (proj₂ m₂) k,v₂∈m₂ k∉km₄))
... | (_ , (in k∉km₁ (single {v₃} v₃∈m₃) , v₃∈m₁m₃)) ... | in k∉km₁ (single {v₃} v₃∈m₃) =
rewrite Map-functional {m = m₁ m₃} k,v∈m₁m₃ v₃∈m₁m₃ =
let (v₄ , (v₃≈v₄ , k,v₄∈m₄)) = proj₁ m₃≈m₄ k v₃ v₃∈m₃ let (v₄ , (v₃≈v₄ , k,v₄∈m₄)) = proj₁ m₃≈m₄ k v₃ v₃∈m₃
k∉km₂ = ≈-∉-cong {m₁} {m₂} m₁≈m₂ k∉km₁ k∉km₂ = ≈-∉-cong {m₁} {m₂} m₁≈m₂ k∉km₁
in (v₄ , (v₃≈v₄ , I⊔.union-preserves-∈₂ k∉km₂ k,v₄∈m₄)) in (v₄ , (v₃≈v₄ , I⊔.union-preserves-∈₂ k∉km₂ k,v₄∈m₄))
@ -690,9 +689,8 @@ private module I⊓ = ImplInsert _⊓₂_
where where
⊓-⊆ : (m₁ m₂ m₃ m₄ : Map) m₁ m₂ m₃ m₄ (m₁ m₃) (m₂ m₄) ⊓-⊆ : (m₁ m₂ m₃ m₄ : Map) m₁ m₂ m₃ m₄ (m₁ m₃) (m₂ m₄)
⊓-⊆ m₁ m₂ m₃ m₄ m₁≈m₂ m₃≈m₄ k v k,v∈m₁m₃ ⊓-⊆ m₁ m₂ m₃ m₄ m₁≈m₂ m₃≈m₄ k v k,v∈m₁m₃
with Expr-Provenance k ((` m₁) (` m₃)) (∈-cong proj₁ k,v∈m₁m₃) with Expr-Provenance-≡ ((` m₁) (` m₃)) k,v∈m₁m₃
... | (_ , (bothⁱ (single {v₁} v₁∈m₁) (single {v₃} v₃∈m₃) , v₁v₃∈m₁m₃)) ... | bothⁱ (single {v₁} v₁∈m₁) (single {v₃} v₃∈m₃) =
rewrite Map-functional {m = m₁ m₃} k,v∈m₁m₃ v₁v₃∈m₁m₃ =
let (v₂ , (v₁≈v₂ , k,v₂∈m₂)) = proj₁ m₁≈m₂ k v₁ v₁∈m₁ let (v₂ , (v₁≈v₂ , k,v₂∈m₂)) = proj₁ m₁≈m₂ k v₁ v₁∈m₁
(v₄ , (v₃≈v₄ , k,v₄∈m₄)) = proj₁ m₃≈m₄ k v₃ v₃∈m₃ (v₄ , (v₃≈v₄ , k,v₄∈m₄)) = proj₁ m₃≈m₄ k v₃ v₃∈m₃
in (v₂ ⊓₂ v₄ , (≈₂-⊓₂-cong v₁≈v₂ v₃≈v₄ , I⊓.intersect-combines (proj₂ m₂) (proj₂ m₄) k,v₂∈m₂ k,v₄∈m₄)) in (v₂ ⊓₂ v₄ , (≈₂-⊓₂-cong v₁≈v₂ v₃≈v₄ , I⊓.intersect-combines (proj₂ m₂) (proj₂ m₄) k,v₂∈m₂ k,v₄∈m₄))
@ -702,13 +700,12 @@ private module I⊓ = ImplInsert _⊓₂_
where where
mm-m-⊆ : (m m) m mm-m-⊆ : (m m) m
mm-m-⊆ k v k,v∈mm mm-m-⊆ k v k,v∈mm
with Expr-Provenance k ((` m) (` m)) (∈-cong proj₁ k,v∈mm) with Expr-Provenance-≡ ((` m) (` m)) k,v∈mm
... | (_ , (bothᵘ (single {v'} v'∈m) (single {v''} v''∈m) , v'v''∈mm)) ... | bothᵘ (single {v'} v'∈m) (single {v''} v''∈m)
rewrite Map-functional {m = m} v'∈m v''∈m rewrite Map-functional {m = m} v'∈m v''∈m =
rewrite Map-functional {m = m m} k,v∈mm v'v''∈mm =
(v'' , (⊔₂-idemp v'' , v''∈m)) (v'' , (⊔₂-idemp v'' , v''∈m))
... | (_ , (in (single {v'} v'∈m) k∉km , _)) = ⊥-elim (k∉km (∈-cong proj₁ v'∈m)) ... | in (single {v'} v'∈m) k∉km = ⊥-elim (k∉km (∈-cong proj₁ v'∈m))
... | (_ , (in k∉km (single {v''} v''∈m) , _)) = ⊥-elim (k∉km (∈-cong proj₁ v''∈m)) ... | in k∉km (single {v''} v''∈m) = ⊥-elim (k∉km (∈-cong proj₁ v''∈m))
m-mm-⊆ : m (m m) m-mm-⊆ : m (m m)
m-mm-⊆ k v k,v∈m = (v ⊔₂ v , (≈₂-sym (⊔₂-idemp v) , I⊔.union-combines u u k,v∈m k,v∈m)) m-mm-⊆ k v k,v∈m = (v ⊔₂ v , (≈₂-sym (⊔₂-idemp v) , I⊔.union-combines u u k,v∈m k,v∈m))
@ -718,15 +715,12 @@ private module I⊓ = ImplInsert _⊓₂_
where where
⊔-comm-⊆ : (m₁ m₂ : Map) (m₁ m₂) (m₂ m₁) ⊔-comm-⊆ : (m₁ m₂ : Map) (m₁ m₂) (m₂ m₁)
⊔-comm-⊆ m₁@(l₁ , u₁) m₂@(l₂ , u₂) k v k,v∈m₁m₂ ⊔-comm-⊆ m₁@(l₁ , u₁) m₂@(l₂ , u₂) k v k,v∈m₁m₂
with Expr-Provenance k ((` m₁) (` m₂)) (∈-cong proj₁ k,v∈m₁m₂) with Expr-Provenance-≡ ((` m₁) (` m₂)) k,v∈m₁m₂
... | (_ , (bothᵘ {v₁} {v₂} (single v₁∈m₁) (single v₂∈m₂) , v₁v₂∈m₁m₂)) ... | bothᵘ {v₁} {v₂} (single v₁∈m₁) (single v₂∈m₂) =
rewrite Map-functional {m = m₁ m₂} k,v∈m₁m₂ v₁v₂∈m₁m₂ =
(v₂ ⊔₂ v₁ , (⊔₂-comm v₁ v₂ , I⊔.union-combines u₂ u₁ v₂∈m₂ v₁∈m₁)) (v₂ ⊔₂ v₁ , (⊔₂-comm v₁ v₂ , I⊔.union-combines u₂ u₁ v₂∈m₂ v₁∈m₁))
... | (_ , (in {v₁} (single v₁∈m₁) k∉km₂ , v₁∈m₁m₂)) ... | in {v₁} (single v₁∈m₁) k∉km₂ =
rewrite Map-functional {m = m₁ m₂} k,v∈m₁m₂ v₁∈m₁m₂ =
(v₁ , (≈₂-refl , I⊔.union-preserves-∈₂ k∉km₂ v₁∈m₁)) (v₁ , (≈₂-refl , I⊔.union-preserves-∈₂ k∉km₂ v₁∈m₁))
... | (_ , (in {v₂} k∉km₁ (single v₂∈m₂) , v₂∈m₁m₂)) ... | in {v₂} k∉km₁ (single v₂∈m₂) =
rewrite Map-functional {m = m₁ m₂} k,v∈m₁m₂ v₂∈m₁m₂ =
(v₂ , (≈₂-refl , I⊔.union-preserves-∈₁ u₂ v₂∈m₂ k∉km₁)) (v₂ , (≈₂-refl , I⊔.union-preserves-∈₁ u₂ v₂∈m₂ k∉km₁))
⊔-assoc : (m₁ m₂ m₃ : Map) ((m₁ m₂) m₃) (m₁ (m₂ m₃)) ⊔-assoc : (m₁ m₂ m₃ : Map) ((m₁ m₂) m₃) (m₁ (m₂ m₃))
@ -734,54 +728,40 @@ private module I⊓ = ImplInsert _⊓₂_
where where
⊔-assoc₁ : ((m₁ m₂) m₃) (m₁ (m₂ m₃)) ⊔-assoc₁ : ((m₁ m₂) m₃) (m₁ (m₂ m₃))
⊔-assoc₁ k v k,v∈m₁₂m₃ ⊔-assoc₁ k v k,v∈m₁₂m₃
with Expr-Provenance k (((` m₁) (` m₂)) (` m₃)) (∈-cong proj₁ k,v∈m₁₂m₃) with Expr-Provenance-≡ (((` m₁) (` m₂)) (` m₃)) k,v∈m₁₂m₃
... | (_ , (in k∉ke₁₂ (single {v₃} v₃∈e₃) , v₃∈m₁₂m₃)) ... | in k∉ke₁₂ (single {v₃} v₃∈e₃) =
rewrite Map-functional {m = (m₁ m₂) m₃} k,v∈m₁₂m₃ v₃∈m₁₂m₃ =
let (k∉ke₁ , k∉ke₂) = I⊔.∉-union-∉-either {l₁ = l₁} {l₂ = l₂} k∉ke₁₂ let (k∉ke₁ , k∉ke₂) = I⊔.∉-union-∉-either {l₁ = l₁} {l₂ = l₂} k∉ke₁₂
in (v₃ , (≈₂-refl , I⊔.union-preserves-∈₂ k∉ke₁ (I⊔.union-preserves-∈₂ k∉ke₂ v₃∈e₃))) in (v₃ , (≈₂-refl , I⊔.union-preserves-∈₂ k∉ke₁ (I⊔.union-preserves-∈₂ k∉ke₂ v₃∈e₃)))
... | (_ , (in (in k∉ke₁ (single {v₂} v₂∈e₂)) k∉ke₃ , v₂∈m₁₂m₃)) ... | in (in k∉ke₁ (single {v₂} v₂∈e₂)) k∉ke₃ =
rewrite Map-functional {m = (m₁ m₂) m₃} k,v∈m₁₂m₃ v₂∈m₁₂m₃ =
(v₂ , (≈₂-refl , I⊔.union-preserves-∈₂ k∉ke₁ (I⊔.union-preserves-∈₁ u₂ v₂∈e₂ k∉ke₃))) (v₂ , (≈₂-refl , I⊔.union-preserves-∈₂ k∉ke₁ (I⊔.union-preserves-∈₁ u₂ v₂∈e₂ k∉ke₃)))
... | (_ , (bothᵘ (in k∉ke₁ (single {v₂} v₂∈e₂)) (single {v₃} v₃∈e₃) , v₂v₃∈m₁₂m₃)) ... | bothᵘ (in k∉ke₁ (single {v₂} v₂∈e₂)) (single {v₃} v₃∈e₃) =
rewrite Map-functional {m = (m₁ m₂) m₃} k,v∈m₁₂m₃ v₂v₃∈m₁₂m₃ =
(v₂ ⊔₂ v₃ , (≈₂-refl , I⊔.union-preserves-∈₂ k∉ke₁ (I⊔.union-combines u₂ u₃ v₂∈e₂ v₃∈e₃))) (v₂ ⊔₂ v₃ , (≈₂-refl , I⊔.union-preserves-∈₂ k∉ke₁ (I⊔.union-combines u₂ u₃ v₂∈e₂ v₃∈e₃)))
... | (_ , (in (in (single {v₁} v₁∈e₁) k∉ke₂) k∉ke₃ , v₁∈m₁₂m₃)) ... | in (in (single {v₁} v₁∈e₁) k∉ke₂) k∉ke₃ =
rewrite Map-functional {m = (m₁ m₂) m₃} k,v∈m₁₂m₃ v₁∈m₁₂m₃ =
(v₁ , (≈₂-refl , I⊔.union-preserves-∈₁ u₁ v₁∈e₁ (I⊔.union-preserves-∉ k∉ke₂ k∉ke₃))) (v₁ , (≈₂-refl , I⊔.union-preserves-∈₁ u₁ v₁∈e₁ (I⊔.union-preserves-∉ k∉ke₂ k∉ke₃)))
... | (_ , (bothᵘ (in (single {v₁} v₁∈e₁) k∉ke₂) (single {v₃} v₃∈e₃) , v₁v₃∈m₁₂m₃)) ... | bothᵘ (in (single {v₁} v₁∈e₁) k∉ke₂) (single {v₃} v₃∈e₃) =
rewrite Map-functional {m = (m₁ m₂) m₃} k,v∈m₁₂m₃ v₁v₃∈m₁₂m₃ =
(v₁ ⊔₂ v₃ , (≈₂-refl , I⊔.union-combines u₁ (I⊔.union-preserves-Unique l₂ l₃ u₃) v₁∈e₁ (I⊔.union-preserves-∈₂ k∉ke₂ v₃∈e₃))) (v₁ ⊔₂ v₃ , (≈₂-refl , I⊔.union-combines u₁ (I⊔.union-preserves-Unique l₂ l₃ u₃) v₁∈e₁ (I⊔.union-preserves-∈₂ k∉ke₂ v₃∈e₃)))
... | (_ , (in (bothᵘ (single {v₁} v₁∈e₁) (single {v₂} v₂∈e₂)) k∉ke₃), v₁v₂∈m₁₂m₃) ... | in (bothᵘ (single {v₁} v₁∈e₁) (single {v₂} v₂∈e₂)) k∉ke₃ =
rewrite Map-functional {m = (m₁ m₂) m₃} k,v∈m₁₂m₃ v₁v₂∈m₁₂m₃ =
(v₁ ⊔₂ v₂ , (≈₂-refl , I⊔.union-combines u₁ (I⊔.union-preserves-Unique l₂ l₃ u₃) v₁∈e₁ (I⊔.union-preserves-∈₁ u₂ v₂∈e₂ k∉ke₃))) (v₁ ⊔₂ v₂ , (≈₂-refl , I⊔.union-combines u₁ (I⊔.union-preserves-Unique l₂ l₃ u₃) v₁∈e₁ (I⊔.union-preserves-∈₁ u₂ v₂∈e₂ k∉ke₃)))
... | (_ , (bothᵘ (bothᵘ (single {v₁} v₁∈e₁) (single {v₂} v₂∈e₂)) (single {v₃} v₃∈e₃) , v₁v₂v₃∈m₁₂m₃)) ... | bothᵘ (bothᵘ (single {v₁} v₁∈e₁) (single {v₂} v₂∈e₂)) (single {v₃} v₃∈e₃) =
rewrite Map-functional {m = (m₁ m₂) m₃} k,v∈m₁₂m₃ v₁v₂v₃∈m₁₂m₃ =
(v₁ ⊔₂ (v₂ ⊔₂ v₃) , (⊔₂-assoc v₁ v₂ v₃ , I⊔.union-combines u₁ (I⊔.union-preserves-Unique l₂ l₃ u₃) v₁∈e₁ (I⊔.union-combines u₂ u₃ v₂∈e₂ v₃∈e₃))) (v₁ ⊔₂ (v₂ ⊔₂ v₃) , (⊔₂-assoc v₁ v₂ v₃ , I⊔.union-combines u₁ (I⊔.union-preserves-Unique l₂ l₃ u₃) v₁∈e₁ (I⊔.union-combines u₂ u₃ v₂∈e₂ v₃∈e₃)))
⊔-assoc₂ : (m₁ (m₂ m₃)) ((m₁ m₂) m₃) ⊔-assoc₂ : (m₁ (m₂ m₃)) ((m₁ m₂) m₃)
⊔-assoc₂ k v k,v∈m₁m₂₃ ⊔-assoc₂ k v k,v∈m₁m₂₃
with Expr-Provenance k ((` m₁) ((` m₂) (` m₃))) (∈-cong proj₁ k,v∈m₁m₂₃) with Expr-Provenance-≡ ((` m₁) ((` m₂) (` m₃))) k,v∈m₁m₂₃
... | (_ , (in k∉ke₁ (in k∉ke₂ (single {v₃} v₃∈e₃)) , v₃∈m₁m₂₃)) ... | in k∉ke₁ (in k∉ke₂ (single {v₃} v₃∈e₃)) =
rewrite Map-functional {m = m₁ (m₂ m₃)} k,v∈m₁m₂₃ v₃∈m₁m₂₃ =
(v₃ , (≈₂-refl , I⊔.union-preserves-∈₂ (I⊔.union-preserves-∉ k∉ke₁ k∉ke₂) v₃∈e₃)) (v₃ , (≈₂-refl , I⊔.union-preserves-∈₂ (I⊔.union-preserves-∉ k∉ke₁ k∉ke₂) v₃∈e₃))
... | (_ , (in k∉ke₁ (in (single {v₂} v₂∈e₂) k∉ke₃) , v₂∈m₁m₂₃)) ... | in k∉ke₁ (in (single {v₂} v₂∈e₂) k∉ke₃) =
rewrite Map-functional {m = m₁ (m₂ m₃)} k,v∈m₁m₂₃ v₂∈m₁m₂₃ =
(v₂ , (≈₂-refl , I⊔.union-preserves-∈₁ (I⊔.union-preserves-Unique l₁ l₂ u₂) (I⊔.union-preserves-∈₂ k∉ke₁ v₂∈e₂) k∉ke₃)) (v₂ , (≈₂-refl , I⊔.union-preserves-∈₁ (I⊔.union-preserves-Unique l₁ l₂ u₂) (I⊔.union-preserves-∈₂ k∉ke₁ v₂∈e₂) k∉ke₃))
... | (_ , (in k∉ke₁ (bothᵘ (single {v₂} v₂∈e₂) (single {v₃} v₃∈e₃)) , v₂v₃∈m₁m₂₃)) ... | in k∉ke₁ (bothᵘ (single {v₂} v₂∈e₂) (single {v₃} v₃∈e₃)) =
rewrite Map-functional {m = m₁ (m₂ m₃)} k,v∈m₁m₂₃ v₂v₃∈m₁m₂₃ =
(v₂ ⊔₂ v₃ , (≈₂-refl , I⊔.union-combines (I⊔.union-preserves-Unique l₁ l₂ u₂) u₃ (I⊔.union-preserves-∈₂ k∉ke₁ v₂∈e₂) v₃∈e₃)) (v₂ ⊔₂ v₃ , (≈₂-refl , I⊔.union-combines (I⊔.union-preserves-Unique l₁ l₂ u₂) u₃ (I⊔.union-preserves-∈₂ k∉ke₁ v₂∈e₂) v₃∈e₃))
... | (_ , (in (single {v₁} v₁∈e₁) k∉ke₂₃ , v₁∈m₁m₂₃)) ... | in (single {v₁} v₁∈e₁) k∉ke₂₃ =
rewrite Map-functional {m = m₁ (m₂ m₃)} k,v∈m₁m₂₃ v₁∈m₁m₂₃ =
let (k∉ke₂ , k∉ke₃) = I⊔.∉-union-∉-either {l₁ = l₂} {l₂ = l₃} k∉ke₂₃ let (k∉ke₂ , k∉ke₃) = I⊔.∉-union-∉-either {l₁ = l₂} {l₂ = l₃} k∉ke₂₃
in (v₁ , (≈₂-refl , I⊔.union-preserves-∈₁ (I⊔.union-preserves-Unique l₁ l₂ u₂) (I⊔.union-preserves-∈₁ u₁ v₁∈e₁ k∉ke₂) k∉ke₃)) in (v₁ , (≈₂-refl , I⊔.union-preserves-∈₁ (I⊔.union-preserves-Unique l₁ l₂ u₂) (I⊔.union-preserves-∈₁ u₁ v₁∈e₁ k∉ke₂) k∉ke₃))
... | (_ , (bothᵘ (single {v₁} v₁∈e₁) (in k∉ke₂ (single {v₃} v₃∈e₃)) , v₁v₃∈m₁m₂₃)) ... | bothᵘ (single {v₁} v₁∈e₁) (in k∉ke₂ (single {v₃} v₃∈e₃)) =
rewrite Map-functional {m = m₁ (m₂ m₃)} k,v∈m₁m₂₃ v₁v₃∈m₁m₂₃ =
(v₁ ⊔₂ v₃ , (≈₂-refl , I⊔.union-combines (I⊔.union-preserves-Unique l₁ l₂ u₂) u₃ (I⊔.union-preserves-∈₁ u₁ v₁∈e₁ k∉ke₂) v₃∈e₃)) (v₁ ⊔₂ v₃ , (≈₂-refl , I⊔.union-combines (I⊔.union-preserves-Unique l₁ l₂ u₂) u₃ (I⊔.union-preserves-∈₁ u₁ v₁∈e₁ k∉ke₂) v₃∈e₃))
... | (_ , (bothᵘ (single {v₁} v₁∈e₁) (in (single {v₂} v₂∈e₂) k∉ke₃) , v₁v₂∈m₁m₂₃)) ... | bothᵘ (single {v₁} v₁∈e₁) (in (single {v₂} v₂∈e₂) k∉ke₃) =
rewrite Map-functional {m = m₁ (m₂ m₃)} k,v∈m₁m₂₃ v₁v₂∈m₁m₂₃ =
(v₁ ⊔₂ v₂ , (≈₂-refl , I⊔.union-preserves-∈₁ (I⊔.union-preserves-Unique l₁ l₂ u₂) (I⊔.union-combines u₁ u₂ v₁∈e₁ v₂∈e₂) k∉ke₃)) (v₁ ⊔₂ v₂ , (≈₂-refl , I⊔.union-preserves-∈₁ (I⊔.union-preserves-Unique l₁ l₂ u₂) (I⊔.union-combines u₁ u₂ v₁∈e₁ v₂∈e₂) k∉ke₃))
... | (_ , (bothᵘ (single {v₁} v₁∈e₁) (bothᵘ (single {v₂} v₂∈e₂) (single {v₃} v₃∈e₃)) , v₁v₂v₃∈m₁m₂₃)) ... | bothᵘ (single {v₁} v₁∈e₁) (bothᵘ (single {v₂} v₂∈e₂) (single {v₃} v₃∈e₃)) =
rewrite Map-functional {m = m₁ (m₂ m₃)} k,v∈m₁m₂₃ v₁v₂v₃∈m₁m₂₃ =
((v₁ ⊔₂ v₂) ⊔₂ v₃ , (≈₂-sym (⊔₂-assoc v₁ v₂ v₃) , I⊔.union-combines (I⊔.union-preserves-Unique l₁ l₂ u₂) u₃ (I⊔.union-combines u₁ u₂ v₁∈e₁ v₂∈e₂) v₃∈e₃)) ((v₁ ⊔₂ v₂) ⊔₂ v₃ , (≈₂-sym (⊔₂-assoc v₁ v₂ v₃) , I⊔.union-combines (I⊔.union-preserves-Unique l₁ l₂ u₂) u₃ (I⊔.union-combines u₁ u₂ v₁∈e₁ v₂∈e₂) v₃∈e₃))
⊓-idemp : (m : Map) (m m) m ⊓-idemp : (m : Map) (m m) m
@ -789,10 +769,9 @@ private module I⊓ = ImplInsert _⊓₂_
where where
mm-m-⊆ : (m m) m mm-m-⊆ : (m m) m
mm-m-⊆ k v k,v∈mm mm-m-⊆ k v k,v∈mm
with Expr-Provenance k ((` m) (` m)) (∈-cong proj₁ k,v∈mm) with Expr-Provenance-≡ ((` m) (` m)) k,v∈mm
... | (_ , (bothⁱ (single {v'} v'∈m) (single {v''} v''∈m) , v'v''∈mm)) ... | bothⁱ (single {v'} v'∈m) (single {v''} v''∈m)
rewrite Map-functional {m = m} v'∈m v''∈m rewrite Map-functional {m = m} v'∈m v''∈m =
rewrite Map-functional {m = m m} k,v∈mm v'v''∈mm =
(v'' , (⊓₂-idemp v'' , v''∈m)) (v'' , (⊓₂-idemp v'' , v''∈m))
m-mm-⊆ : m (m m) m-mm-⊆ : m (m m)
@ -803,9 +782,8 @@ private module I⊓ = ImplInsert _⊓₂_
where where
⊓-comm-⊆ : (m₁ m₂ : Map) (m₁ m₂) (m₂ m₁) ⊓-comm-⊆ : (m₁ m₂ : Map) (m₁ m₂) (m₂ m₁)
⊓-comm-⊆ m₁@(l₁ , u₁) m₂@(l₂ , u₂) k v k,v∈m₁m₂ ⊓-comm-⊆ m₁@(l₁ , u₁) m₂@(l₂ , u₂) k v k,v∈m₁m₂
with Expr-Provenance k ((` m₁) (` m₂)) (∈-cong proj₁ k,v∈m₁m₂) with Expr-Provenance-≡ ((` m₁) (` m₂)) k,v∈m₁m₂
... | (_ , (bothⁱ {v₁} {v₂} (single v₁∈m₁) (single v₂∈m₂) , v₁v₂∈m₁m₂)) ... | bothⁱ {v₁} {v₂} (single v₁∈m₁) (single v₂∈m₂) =
rewrite Map-functional {m = m₁ m₂} k,v∈m₁m₂ v₁v₂∈m₁m₂ =
(v₂ ⊓₂ v₁ , (⊓₂-comm v₁ v₂ , I⊓.intersect-combines u₂ u₁ v₂∈m₂ v₁∈m₁)) (v₂ ⊓₂ v₁ , (⊓₂-comm v₁ v₂ , I⊓.intersect-combines u₂ u₁ v₂∈m₂ v₁∈m₁))
⊓-assoc : (m₁ m₂ m₃ : Map) ((m₁ m₂) m₃) (m₁ (m₂ m₃)) ⊓-assoc : (m₁ m₂ m₃ : Map) ((m₁ m₂) m₃) (m₁ (m₂ m₃))
@ -813,16 +791,14 @@ private module I⊓ = ImplInsert _⊓₂_
where where
⊓-assoc₁ : ((m₁ m₂) m₃) (m₁ (m₂ m₃)) ⊓-assoc₁ : ((m₁ m₂) m₃) (m₁ (m₂ m₃))
⊓-assoc₁ k v k,v∈m₁₂m₃ ⊓-assoc₁ k v k,v∈m₁₂m₃
with Expr-Provenance k (((` m₁) (` m₂)) (` m₃)) (∈-cong proj₁ k,v∈m₁₂m₃) with Expr-Provenance-≡ (((` m₁) (` m₂)) (` m₃)) k,v∈m₁₂m₃
... | (_ , (bothⁱ (bothⁱ (single {v₁} v₁∈e₁) (single {v₂} v₂∈e₂)) (single {v₃} v₃∈e₃) , v₁v₂v₃∈m₁₂m₃)) ... | bothⁱ (bothⁱ (single {v₁} v₁∈e₁) (single {v₂} v₂∈e₂)) (single {v₃} v₃∈e₃) =
rewrite Map-functional {m = (m₁ m₂) m₃} k,v∈m₁₂m₃ v₁v₂v₃∈m₁₂m₃ =
(v₁ ⊓₂ (v₂ ⊓₂ v₃) , (⊓₂-assoc v₁ v₂ v₃ , I⊓.intersect-combines u₁ (I⊓.intersect-preserves-Unique {l₂} {l₃} u₃) v₁∈e₁ (I⊓.intersect-combines u₂ u₃ v₂∈e₂ v₃∈e₃))) (v₁ ⊓₂ (v₂ ⊓₂ v₃) , (⊓₂-assoc v₁ v₂ v₃ , I⊓.intersect-combines u₁ (I⊓.intersect-preserves-Unique {l₂} {l₃} u₃) v₁∈e₁ (I⊓.intersect-combines u₂ u₃ v₂∈e₂ v₃∈e₃)))
⊓-assoc₂ : (m₁ (m₂ m₃)) ((m₁ m₂) m₃) ⊓-assoc₂ : (m₁ (m₂ m₃)) ((m₁ m₂) m₃)
⊓-assoc₂ k v k,v∈m₁m₂₃ ⊓-assoc₂ k v k,v∈m₁m₂₃
with Expr-Provenance k ((` m₁) ((` m₂) (` m₃))) (∈-cong proj₁ k,v∈m₁m₂₃) with Expr-Provenance-≡ ((` m₁) ((` m₂) (` m₃))) k,v∈m₁m₂₃
... | (_ , (bothⁱ (single {v₁} v₁∈e₁) (bothⁱ (single {v₂} v₂∈e₂) (single {v₃} v₃∈e₃)) , v₁v₂v₃∈m₁m₂₃)) ... | bothⁱ (single {v₁} v₁∈e₁) (bothⁱ (single {v₂} v₂∈e₂) (single {v₃} v₃∈e₃)) =
rewrite Map-functional {m = m₁ (m₂ m₃)} k,v∈m₁m₂₃ v₁v₂v₃∈m₁m₂₃ =
((v₁ ⊓₂ v₂) ⊓₂ v₃ , (≈₂-sym (⊓₂-assoc v₁ v₂ v₃) , I⊓.intersect-combines (I⊓.intersect-preserves-Unique {l₁} {l₂} u₂) u₃ (I⊓.intersect-combines u₁ u₂ v₁∈e₁ v₂∈e₂) v₃∈e₃)) ((v₁ ⊓₂ v₂) ⊓₂ v₃ , (≈₂-sym (⊓₂-assoc v₁ v₂ v₃) , I⊓.intersect-combines (I⊓.intersect-preserves-Unique {l₁} {l₂} u₂) u₃ (I⊓.intersect-combines u₁ u₂ v₁∈e₁ v₂∈e₂) v₃∈e₃))
absorb-⊓-⊔ : (m₁ m₂ : Map) (m₁ (m₁ m₂)) m₁ absorb-⊓-⊔ : (m₁ m₂ : Map) (m₁ (m₁ m₂)) m₁
@ -830,20 +806,18 @@ absorb-⊓-⊔ m₁@(l₁ , u₁) m₂@(l₂ , u₂) = (absorb-⊓-⊔¹ , absor
where where
absorb-⊓-⊔¹ : (m₁ (m₁ m₂)) m₁ absorb-⊓-⊔¹ : (m₁ (m₁ m₂)) m₁
absorb-⊓-⊔¹ k v k,v∈m₁m₁₂ absorb-⊓-⊔¹ k v k,v∈m₁m₁₂
with Expr-Provenance k ((` m₁) ((` m₁) (` m₂))) (∈-cong proj₁ k,v∈m₁m₁₂) with Expr-Provenance-≡ ((` m₁) ((` m₁) (` m₂))) k,v∈m₁m₁₂
... | (_ , (bothⁱ (single {v₁} k,v₁∈m₁) ... | bothⁱ (single {v₁} k,v₁∈m₁)
(bothᵘ (single {v₁'} k,v₁'∈m₁) (bothᵘ (single {v₁'} k,v₁'∈m₁)
(single {v₂} v₂∈m₂)) , v₁v₁'v₂∈m₁m₁₂)) (single {v₂} v₂∈m₂))
rewrite Map-functional {m = m₁} k,v₁∈m₁ k,v₁'∈m₁ rewrite Map-functional {m = m₁} k,v₁∈m₁ k,v₁'∈m₁ =
rewrite Map-functional {m = m₁ (m₁ m₂)} k,v∈m₁m₁₂ v₁v₁'v₂∈m₁m₁₂ =
(v₁' , (absorb-⊓₂-⊔₂ v₁' v₂ , k,v₁'∈m₁)) (v₁' , (absorb-⊓₂-⊔₂ v₁' v₂ , k,v₁'∈m₁))
... | (_ , (bothⁱ (single {v₁} k,v₁∈m₁) ... | bothⁱ (single {v₁} k,v₁∈m₁)
(in (single {v₁'} k,v₁'∈m₁) _) , v₁v₁'∈m₁m₁₂)) (in (single {v₁'} k,v₁'∈m₁) _)
rewrite Map-functional {m = m₁} k,v₁∈m₁ k,v₁'∈m₁ rewrite Map-functional {m = m₁} k,v₁∈m₁ k,v₁'∈m₁ =
rewrite Map-functional {m = m₁ (m₁ m₂)} k,v∈m₁m₁₂ v₁v₁'∈m₁m₁₂ =
(v₁' , (⊓₂-idemp v₁' , k,v₁'∈m₁)) (v₁' , (⊓₂-idemp v₁' , k,v₁'∈m₁))
... | (_ , (bothⁱ (single {v₁} k,v₁∈m₁) ... | bothⁱ (single {v₁} k,v₁∈m₁)
(in k∉m₁ _ ) , _)) = ⊥-elim (k∉m₁ (∈-cong proj₁ k,v₁∈m₁)) (in k∉m₁ _ ) = ⊥-elim (k∉m₁ (∈-cong proj₁ k,v₁∈m₁))
absorb-⊓-⊔² : m₁ (m₁ (m₁ m₂)) absorb-⊓-⊔² : m₁ (m₁ (m₁ m₂))
absorb-⊓-⊔² k v k,v∈m₁ absorb-⊓-⊔² k v k,v∈m₁
@ -858,18 +832,16 @@ absorb-⊔-⊓ m₁@(l₁ , u₁) m₂@(l₂ , u₂) = (absorb-⊔-⊓¹ , absor
where where
absorb-⊔-⊓¹ : (m₁ (m₁ m₂)) m₁ absorb-⊔-⊓¹ : (m₁ (m₁ m₂)) m₁
absorb-⊔-⊓¹ k v k,v∈m₁m₁₂ absorb-⊔-⊓¹ k v k,v∈m₁m₁₂
with Expr-Provenance k ((` m₁) ((` m₁) (` m₂))) (∈-cong proj₁ k,v∈m₁m₁₂) with Expr-Provenance-≡ ((` m₁) ((` m₁) (` m₂))) k,v∈m₁m₁₂
... | (_ , (bothᵘ (single {v₁} k,v₁∈m₁) ... | bothᵘ (single {v₁} k,v₁∈m₁)
(bothⁱ (single {v₁'} k,v₁'∈m₁) (bothⁱ (single {v₁'} k,v₁'∈m₁)
(single {v₂} k,v₂∈m₂)) , v₁v₁'v₂∈m₁m₁₂)) (single {v₂} k,v₂∈m₂))
rewrite Map-functional {m = m₁} k,v₁∈m₁ k,v₁'∈m₁ rewrite Map-functional {m = m₁} k,v₁∈m₁ k,v₁'∈m₁ =
rewrite Map-functional {m = m₁ (m₁ m₂)} k,v∈m₁m₁₂ v₁v₁'v₂∈m₁m₁₂ =
(v₁' , (absorb-⊔₂-⊓₂ v₁' v₂ , k,v₁'∈m₁)) (v₁' , (absorb-⊔₂-⊓₂ v₁' v₂ , k,v₁'∈m₁))
... | (_ , (in (single {v₁} k,v₁∈m₁) k∉km₁₂ , k,v₁∈m₁m₁₂)) ... | in (single {v₁} k,v₁∈m₁) k∉km₁₂ =
rewrite Map-functional {m = m₁ (m₁ m₂)} k,v∈m₁m₁₂ k,v₁∈m₁m₁₂ =
(v₁ , (≈₂-refl , k,v₁∈m₁)) (v₁ , (≈₂-refl , k,v₁∈m₁))
... | (_ , (in k∉km₁ (bothⁱ (single {v₁'} k,v₁'∈m₁) ... | in k∉km₁ (bothⁱ (single {v₁'} k,v₁'∈m₁)
(single {v₂} k,v₂∈m₂)) , _)) = (single {v₂} k,v₂∈m₂)) =
⊥-elim (k∉km₁ (∈-cong proj₁ k,v₁'∈m₁)) ⊥-elim (k∉km₁ (∈-cong proj₁ k,v₁'∈m₁))
absorb-⊔-⊓² : m₁ (m₁ (m₁ m₂)) absorb-⊔-⊓² : m₁ (m₁ (m₁ m₂))
@ -1009,7 +981,7 @@ updating-via-k∈ks-forward m {ks} f k∈ks k∈km rewrite transform-keys-≡ (p
updating-via-k∈ks-≡ : (m : Map) {ks : List A} (f : A B) {k : A} {v : B} updating-via-k∈ks-≡ : (m : Map) {ks : List A} (f : A B) {k : A} {v : B}
k ∈ˡ ks (k , v) (m updating ks via f) v f k k ∈ˡ ks (k , v) (m updating ks via f) v f k
updating-via-k∈ks-≡ m {ks} f k∈ks k,v∈um updating-via-k∈ks-≡ m {ks} f k∈ks k,v∈um
with updating-via-k∈ks m f k∈ks (forget {m = (m updating ks via f)} k,v∈um) with updating-via-k∈ks m f k∈ks (forget k,v∈um)
... | k,fk∈um = Map-functional {m = (m updating ks via f)} k,v∈um k,fk∈um ... | k,fk∈um = Map-functional {m = (m updating ks via f)} k,v∈um k,fk∈um
updating-via-k∉ks-forward : (m : Map) {ks : List A} (f : A B) {k : A} {v : B} updating-via-k∉ks-forward : (m : Map) {ks : List A} (f : A B) {k : A} {v : B}
@ -1044,14 +1016,14 @@ module _ {l} {L : Set l}
f'l₁f'l₂⊆f'l₂ : ((f' l₁) (f' l₂)) f' l₂ f'l₁f'l₂⊆f'l₂ : ((f' l₁) (f' l₂)) f' l₂
f'l₁f'l₂⊆f'l₂ k v k,v∈f'l₁f'l₂ f'l₁f'l₂⊆f'l₂ k v k,v∈f'l₁f'l₂
with Expr-Provenance-≡ k v ((` (f' l₁)) (` (f' l₂))) k,v∈f'l₁f'l₂ with Expr-Provenance-≡ ((` (f' l₁)) (` (f' l₂))) k,v∈f'l₁f'l₂
... | in (single k,v∈f'l₁) k∉kf'l₂ = ... | in (single k,v∈f'l₁) k∉kf'l₂ =
let let
k∈kfl₁ = updating-via-∈k-backward (f l₁) ks (updater l₁) (forget {m = f' l₁} k,v∈f'l₁) k∈kfl₁ = updating-via-∈k-backward (f l₁) ks (updater l₁) (forget k,v∈f'l₁)
k∈kfl₁fl₂ = union-preserves-∈k₁ {l₁ = proj₁ (f l₁)} {l₂ = proj₁ (f l₂)} k∈kfl₁ k∈kfl₁fl₂ = union-preserves-∈k₁ {l₁ = proj₁ (f l₁)} {l₂ = proj₁ (f l₂)} k∈kfl₁
(v' , k,v'∈fl₁l₂) = locate {m = (f l₁ f l₂)} k∈kfl₁fl₂ (v' , k,v'∈fl₁l₂) = locate {m = (f l₁ f l₂)} k∈kfl₁fl₂
(v'' , (v'≈v'' , k,v''∈fl₂)) = fl₁fl₂⊆fl₂ k v' k,v'∈fl₁l₂ (v'' , (v'≈v'' , k,v''∈fl₂)) = fl₁fl₂⊆fl₂ k v' k,v'∈fl₁l₂
k∈kf'l₂ = updating-via-∈k-forward (f l₂) ks (updater l₂) (forget {m = f l₂} k,v''∈fl₂) k∈kf'l₂ = updating-via-∈k-forward (f l₂) ks (updater l₂) (forget k,v''∈fl₂)
in in
⊥-elim (k∉kf'l₂ k∈kf'l₂) ⊥-elim (k∉kf'l₂ k∈kf'l₂)
... | in k∉kf'l₁ (single k,v'∈f'l₂) = ... | in k∉kf'l₁ (single k,v'∈f'l₂) =
@ -1074,10 +1046,10 @@ module _ {l} {L : Set l}
f'l₂⊆f'l₁f'l₂ : f' l₂ ((f' l₁) (f' l₂)) f'l₂⊆f'l₁f'l₂ : f' l₂ ((f' l₁) (f' l₂))
f'l₂⊆f'l₁f'l₂ k v k,v∈f'l₂ f'l₂⊆f'l₁f'l₂ k v k,v∈f'l₂
with k∈kfl₂ updating-via-∈k-backward (f l₂) ks (updater l₂) (forget {m = f' l₂} k,v∈f'l₂) with k∈kfl₂ updating-via-∈k-backward (f l₂) ks (updater l₂) (forget k,v∈f'l₂)
with (v' , k,v'∈fl₂) locate {m = f l₂} k∈kfl₂ with (v' , k,v'∈fl₂) locate {m = f l₂} k∈kfl₂
with (v'' , (v'≈v'' , k,v''∈fl₁fl₂)) fl₂⊆fl₁fl₂ k v' k,v'∈fl₂ with (v'' , (v'≈v'' , k,v''∈fl₁fl₂)) fl₂⊆fl₁fl₂ k v' k,v'∈fl₂
with Expr-Provenance-≡ k v'' ((` (f l₁)) (` (f l₂))) k,v''∈fl₁fl₂ with Expr-Provenance-≡ ((` (f l₁)) (` (f l₂))) k,v''∈fl₁fl₂
... | in (single k,v''∈fl₁) k∉kfl₂ = ⊥-elim (k∉kfl₂ k∈kfl₂) ... | in (single k,v''∈fl₁) k∉kfl₂ = ⊥-elim (k∉kfl₂ k∈kfl₂)
... | in k∉kfl₁ (single k,v''∈fl₂) = ... | in k∉kfl₁ (single k,v''∈fl₂) =
let let
@ -1088,8 +1060,8 @@ module _ {l} {L : Set l}
with k∈-dec k ks with k∈-dec k ks
... | yes k∈ks with refl updating-via-k∈ks-≡ (f l₂) (updater l₂) k∈ks k,v∈f'l₂ = ... | yes k∈ks with refl updating-via-k∈ks-≡ (f l₂) (updater l₂) k∈ks k,v∈f'l₂ =
let let
k,uv₁∈f'l₁ = updating-via-k∈ks-forward (f l₁) (updater l₁) k∈ks (forget {m = f l₁} k,v₁∈fl₁) k,uv₁∈f'l₁ = updating-via-k∈ks-forward (f l₁) (updater l₁) k∈ks (forget k,v₁∈fl₁)
k,uv₂∈f'l₂ = updating-via-k∈ks-forward (f l₂) (updater l₂) k∈ks (forget {m = f l₂} k,v₂∈fl₂) k,uv₂∈f'l₂ = updating-via-k∈ks-forward (f l₂) (updater l₂) k∈ks (forget k,v₂∈fl₂)
k,uv₁uv₂∈f'l₁f'l₂ = ⊔-combines {m₁ = f' l₁} {m₂ = f' l₂} k,uv₁∈f'l₁ k,uv₂∈f'l₂ k,uv₁uv₂∈f'l₁f'l₂ = ⊔-combines {m₁ = f' l₁} {m₂ = f' l₂} k,uv₁∈f'l₁ k,uv₂∈f'l₂
in in
(updater l₁ k ⊔₂ updater l₂ k , (IsLattice.≈-sym lB (g-Monotonicʳ k l₁≼l₂) , k,uv₁uv₂∈f'l₁f'l₂)) (updater l₁ k ⊔₂ updater l₂ k , (IsLattice.≈-sym lB (g-Monotonicʳ k l₁≼l₂) , k,uv₁uv₂∈f'l₁f'l₂))

View File

@ -1,5 +1,6 @@
module Utils where module Utils where
open import Agda.Primitive using () renaming (_⊔_ to _⊔_)
open import Data.Nat using (; suc) open import Data.Nat using (; suc)
open import Data.List using (List; []; _∷_; _++_) open import Data.List using (List; []; _∷_; _++_)
open import Data.List.Membership.Propositional using (_∈_) open import Data.List.Membership.Propositional using (_∈_)
@ -43,3 +44,9 @@ All-x∈xs (x ∷ xs') = here refl ∷ map there (All-x∈xs xs')
iterate : {a} {A : Set a} (n : ) (f : A A) A A iterate : {a} {A : Set a} (n : ) (f : A A) A A
iterate 0 _ a = a iterate 0 _ a = a
iterate (suc n) f a = f (iterate n f a) iterate (suc n) f a = f (iterate n f a)
data Pairwise {a} {b} {c} {A : Set a} {B : Set b} (P : A B Set c) : List A List B Set (a ⊔ℓ b ⊔ℓ c) where
[] : Pairwise P [] []
_∷_ : {x : A} {y : B} {xs : List A} {ys : List B}
P x y Pairwise P xs ys
Pairwise P (x xs) (y ys)