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| author | Shinji KONO <kono@ie.u-ryukyu.ac.jp> |
|---|---|
| date | Sat, 12 Dec 2020 20:28:29 +0900 |
| parents | 3c7e8855996f |
| children |
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{-# OPTIONS --allow-unsolved-metas #-} module Putil where open import Level hiding ( suc ; zero ) open import Algebra open import Algebra.Structures open import Data.Fin hiding ( _<_ ; _≤_ ; _-_ ; _+_ ; _≟_) open import Data.Fin.Properties hiding ( <-trans ; ≤-trans ; ≤-irrelevant ; _≟_ ) renaming ( <-cmp to <-fcmp ) open import Data.Fin.Permutation open import Function hiding (id ; flip) open import Function.Inverse as Inverse using (_↔_; Inverse; _InverseOf_) open import Function.LeftInverse using ( _LeftInverseOf_ ) open import Function.Equality using (Π) open import Data.Nat -- using (ℕ; suc; zero; s≤s ; z≤n ) open import Data.Nat.Properties -- using (<-trans) open import Relation.Binary.PropositionalEquality hiding ( [_] ) open import Data.List using (List; []; _∷_ ; length ; _++_ ; head ; tail ) renaming (reverse to rev ) open import nat open import Symmetric open import Relation.Nullary open import Data.Empty open import Relation.Binary.Core open import Relation.Binary.Definitions open import fin -- An inductive construction of permutation pprep : {n : ℕ } → Permutation n n → Permutation (suc n) (suc n) pprep {n} perm = permutation p→ p← record { left-inverse-of = piso→ ; right-inverse-of = piso← } where p→ : Fin (suc n) → Fin (suc n) p→ zero = zero p→ (suc x) = suc ( perm ⟨$⟩ʳ x) p← : Fin (suc n) → Fin (suc n) p← zero = zero p← (suc x) = suc ( perm ⟨$⟩ˡ x) piso← : (x : Fin (suc n)) → p→ ( p← x ) ≡ x piso← zero = refl piso← (suc x) = cong (λ k → suc k ) (inverseʳ perm) piso→ : (x : Fin (suc n)) → p← ( p→ x ) ≡ x piso→ zero = refl piso→ (suc x) = cong (λ k → suc k ) (inverseˡ perm) pswap : {n : ℕ } → Permutation n n → Permutation (suc (suc n)) (suc (suc n )) pswap {n} perm = permutation p→ p← record { left-inverse-of = piso→ ; right-inverse-of = piso← } where p→ : Fin (suc (suc n)) → Fin (suc (suc n)) p→ zero = suc zero p→ (suc zero) = zero p→ (suc (suc x)) = suc ( suc ( perm ⟨$⟩ʳ x) ) p← : Fin (suc (suc n)) → Fin (suc (suc n)) p← zero = suc zero p← (suc zero) = zero p← (suc (suc x)) = suc ( suc ( perm ⟨$⟩ˡ x) ) piso← : (x : Fin (suc (suc n)) ) → p→ ( p← x ) ≡ x piso← zero = refl piso← (suc zero) = refl piso← (suc (suc x)) = cong (λ k → suc (suc k) ) (inverseʳ perm) piso→ : (x : Fin (suc (suc n)) ) → p← ( p→ x ) ≡ x piso→ zero = refl piso→ (suc zero) = refl piso→ (suc (suc x)) = cong (λ k → suc (suc k) ) (inverseˡ perm) psawpn : {n : ℕ} → 1 < n → Permutation n n psawpn {suc zero} (s≤s ()) psawpn {suc n} (s≤s (s≤s x)) = pswap pid pfill : { n m : ℕ } → m ≤ n → Permutation m m → Permutation n n pfill {n} {m} m≤n perm = pfill1 (n - m) (n-m<n n m ) (subst (λ k → Permutation k k ) (n-n-m=m m≤n ) perm) where pfill1 : (i : ℕ ) → i ≤ n → Permutation (n - i) (n - i) → Permutation n n pfill1 0 _ perm = perm pfill1 (suc i) i<n perm = pfill1 i (≤to< i<n) (subst (λ k → Permutation k k ) (si-sn=i-n i<n ) ( pprep perm ) ) -- -- psawpim (inseert swap at position m ) -- psawpim : {n m : ℕ} → suc (suc m) ≤ n → Permutation n n psawpim {n} {m} m≤n = pfill m≤n ( psawpn (s≤s (s≤s z≤n)) ) n≤ : (i : ℕ ) → {j : ℕ } → i ≤ i + j n≤ (zero) {j} = z≤n n≤ (suc i) {j} = s≤s ( n≤ i ) lem0 : {n : ℕ } → n ≤ n lem0 {zero} = z≤n lem0 {suc n} = s≤s lem0 lem00 : {n m : ℕ } → n ≡ m → n ≤ m lem00 refl = lem0 plist1 : {n : ℕ} → Permutation (suc n) (suc n) → (i : ℕ ) → i < suc n → List ℕ plist1 {n} perm zero _ = toℕ ( perm ⟨$⟩ˡ (fromℕ< {zero} (s≤s z≤n))) ∷ [] plist1 {n} perm (suc i) (s≤s lt) = toℕ ( perm ⟨$⟩ˡ (fromℕ< (s≤s lt))) ∷ plist1 perm i (<-trans lt a<sa) plist : {n : ℕ} → Permutation n n → List ℕ plist {0} perm = [] plist {suc n} perm = rev (plist1 perm n a<sa) -- -- from n-1 length create n length inserting new element at position m -- -- 0 ∷ 1 ∷ 2 ∷ 3 ∷ [] -- 0 ∷ 1 ∷ 2 ∷ 3 ∷ [] -- 1 ∷ 0 ∷ 2 ∷ 3 ∷ [] plist ( pins {3} (n≤ 1) ) 1 ∷ 0 ∷ 2 ∷ 3 ∷ [] -- 1 ∷ 2 ∷ 0 ∷ 3 ∷ [] plist ( pins {3} (n≤ 2) ) 2 ∷ 0 ∷ 1 ∷ 3 ∷ [] -- 1 ∷ 2 ∷ 3 ∷ 0 ∷ [] plist ( pins {3} (n≤ 3) ) 3 ∷ 0 ∷ 1 ∷ 2 ∷ [] -- -- defined by pprep and pswap -- -- pins : {n m : ℕ} → m ≤ n → Permutation (suc n) (suc n) -- pins {_} {zero} _ = pid -- pins {suc _} {suc zero} _ = pswap pid -- pins {suc (suc n)} {suc m} (s≤s m<n) = pins1 (suc m) (suc (suc n)) lem0 where -- pins1 : (i j : ℕ ) → j ≤ suc (suc n) → Permutation (suc (suc (suc n ))) (suc (suc (suc n))) -- pins1 _ zero _ = pid -- pins1 zero _ _ = pid -- pins1 (suc i) (suc j) (s≤s si≤n) = psawpim {suc (suc (suc n))} {j} (s≤s (s≤s si≤n)) ∘ₚ pins1 i j (≤-trans si≤n a≤sa ) open import Relation.Binary.HeterogeneousEquality as HE using (_≅_ ) open ≡-Reasoning pins : {n m : ℕ} → m ≤ n → Permutation (suc n) (suc n) pins {_} {zero} _ = pid pins {suc n} {suc m} (s≤s m≤n) = permutation p← p→ record { left-inverse-of = piso← ; right-inverse-of = piso→ } where next : Fin (suc (suc n)) → Fin (suc (suc n)) next zero = suc zero next (suc x) = fromℕ< (≤-trans (fin<n {_} {x} ) a≤sa ) p→ : Fin (suc (suc n)) → Fin (suc (suc n)) p→ x with <-cmp (toℕ x) (suc m) ... | tri< a ¬b ¬c = fromℕ< (≤-trans (s≤s a) (s≤s (s≤s m≤n) )) ... | tri≈ ¬a b ¬c = zero ... | tri> ¬a ¬b c = x p← : Fin (suc (suc n)) → Fin (suc (suc n)) p← zero = fromℕ< (s≤s (s≤s m≤n)) p← (suc x) with <-cmp (toℕ x) (suc m) ... | tri< a ¬b ¬c = fromℕ< (≤-trans (fin<n {_} {x}) a≤sa ) ... | tri≈ ¬a b ¬c = suc x ... | tri> ¬a ¬b c = suc x mm : toℕ (fromℕ< {suc m} {suc (suc n)} (s≤s (s≤s m≤n))) ≡ suc m mm = toℕ-fromℕ< (s≤s (s≤s m≤n)) mma : (x : Fin (suc n) ) → suc (toℕ x) ≤ suc m → toℕ ( fromℕ< (≤-trans (fin<n {_} {x}) a≤sa ) ) ≤ m mma x (s≤s x<sm) = subst (λ k → k ≤ m) (sym (toℕ-fromℕ< (≤-trans fin<n a≤sa ) )) x<sm p3 : (x : Fin (suc n) ) → toℕ (fromℕ< (≤-trans (fin<n {_} {suc x} ) (s≤s a≤sa))) ≡ suc (toℕ x) p3 x = begin toℕ (fromℕ< (≤-trans (fin<n {_} {suc x} ) (s≤s a≤sa))) ≡⟨ toℕ-fromℕ< ( s≤s ( ≤-trans fin<n a≤sa ) ) ⟩ suc (toℕ x) ∎ piso→ : (x : Fin (suc (suc n)) ) → p← ( p→ x ) ≡ x piso→ zero with <-cmp (toℕ (fromℕ< (≤-trans (s≤s z≤n) (s≤s (s≤s m≤n) )))) (suc m) ... | tri< a ¬b ¬c = refl piso→ (suc x) with <-cmp (toℕ (suc x)) (suc m) ... | tri≈ ¬a refl ¬c = p13 where p13 : fromℕ< (s≤s (s≤s m≤n)) ≡ suc x p13 = cong (λ k → suc k ) (fromℕ<-toℕ _ (s≤s m≤n) ) ... | tri> ¬a ¬b c = p16 (suc x) refl where p16 : (y : Fin (suc (suc n))) → y ≡ suc x → p← y ≡ suc x p16 zero eq = ⊥-elim ( nat-≡< (cong (λ k → suc (toℕ k) ) eq) (s≤s (s≤s (z≤n)))) p16 (suc y) eq with <-cmp (toℕ y) (suc m) -- suc (suc m) < toℕ (suc x) ... | tri< a ¬b ¬c = ⊥-elim ( nat-≡< refl ( ≤-trans c (subst (λ k → k < suc m) p17 a )) ) where -- x = suc m case, c : suc (suc m) ≤ suc (toℕ x), a : suc (toℕ y) ≤ suc m, suc y ≡ suc x p17 : toℕ y ≡ toℕ x p17 with <-cmp (toℕ y) (toℕ x) | cong toℕ eq ... | tri< a ¬b ¬c | seq = ⊥-elim ( nat-≡< seq (s≤s a) ) ... | tri≈ ¬a b ¬c | seq = b ... | tri> ¬a ¬b c | seq = ⊥-elim ( nat-≡< (sym seq) (s≤s c)) ... | tri≈ ¬a b ¬c = eq ... | tri> ¬a ¬b c₁ = eq ... | tri< a ¬b ¬c = p10 (fromℕ< (≤-trans (s≤s a) (s≤s (s≤s m≤n) ))) refl where p10 : (y : Fin (suc (suc n)) ) → y ≡ fromℕ< (≤-trans (s≤s a) (s≤s (s≤s m≤n) )) → p← y ≡ suc x p10 zero () p10 (suc y) eq = p15 where p12 : toℕ y ≡ suc (toℕ x) p12 = begin toℕ y ≡⟨ cong (λ k → Data.Nat.pred (toℕ k)) eq ⟩ toℕ (fromℕ< (≤-trans a (s≤s m≤n))) ≡⟨ toℕ-fromℕ< {suc (toℕ x)} {suc n} (≤-trans a (s≤s m≤n)) ⟩ suc (toℕ x) ∎ p15 : p← (suc y) ≡ suc x p15 with <-cmp (toℕ y) (suc m) -- eq : suc y ≡ suc (suc (fromℕ< (≤-pred (≤-trans a (s≤s m≤n))))) , a : suc x < suc m ... | tri< a₁ ¬b ¬c = p11 where p11 : fromℕ< (≤-trans (fin<n {_} {y}) a≤sa ) ≡ suc x p11 = begin fromℕ< (≤-trans (fin<n {_} {y}) a≤sa ) ≡⟨ lemma10 {suc (suc n)} {_} {_} p12 {≤-trans (fin<n {_} {y}) a≤sa} {s≤s (fin<n {suc n} {x} )} ⟩ suc (fromℕ< (fin<n {suc n} {x} )) ≡⟨ cong suc (fromℕ<-toℕ x _ ) ⟩ suc x ∎ ... | tri≈ ¬a b ¬c = ⊥-elim ( nat-≡< b (subst (λ k → k < suc m) (sym p12) a )) -- suc x < suc m -> y = suc x → toℕ y < suc m ... | tri> ¬a ¬b c = ⊥-elim ( nat-<> c (subst (λ k → k < suc m) (sym p12) a )) piso← : (x : Fin (suc (suc n)) ) → p→ ( p← x ) ≡ x piso← zero with <-cmp (toℕ (fromℕ< (s≤s (s≤s m≤n)))) (suc m) | mm ... | tri< a ¬b ¬c | t = ⊥-elim ( ¬b t ) ... | tri≈ ¬a b ¬c | t = refl ... | tri> ¬a ¬b c | t = ⊥-elim ( ¬b t ) piso← (suc x) with <-cmp (toℕ x) (suc m) ... | tri> ¬a ¬b c with <-cmp (toℕ (suc x)) (suc m) ... | tri< a ¬b₁ ¬c = ⊥-elim ( nat-<> a (<-trans c a<sa ) ) ... | tri≈ ¬a₁ b ¬c = ⊥-elim ( nat-≡< (sym b) (<-trans c a<sa )) ... | tri> ¬a₁ ¬b₁ c₁ = refl piso← (suc x) | tri≈ ¬a b ¬c with <-cmp (toℕ (suc x)) (suc m) ... | tri< a ¬b ¬c₁ = ⊥-elim ( nat-≡< b (<-trans a<sa a) ) ... | tri≈ ¬a₁ refl ¬c₁ = ⊥-elim ( nat-≡< b a<sa ) ... | tri> ¬a₁ ¬b c = refl piso← (suc x) | tri< a ¬b ¬c with <-cmp (toℕ ( fromℕ< (≤-trans (fin<n {_} {x}) a≤sa ) )) (suc m) ... | tri≈ ¬a b ¬c₁ = ⊥-elim ( ¬a (s≤s (mma x a))) ... | tri> ¬a ¬b₁ c = ⊥-elim ( ¬a (s≤s (mma x a))) ... | tri< a₁ ¬b₁ ¬c₁ = p0 where p2 : suc (suc (toℕ x)) ≤ suc (suc n) p2 = s≤s (fin<n {suc n} {x}) p6 : suc (toℕ (fromℕ< (≤-trans (fin<n {_} {suc x}) (s≤s a≤sa)))) ≤ suc (suc n) p6 = s≤s (≤-trans a₁ (s≤s m≤n)) p0 : fromℕ< (≤-trans (s≤s a₁) (s≤s (s≤s m≤n) )) ≡ suc x p0 = begin fromℕ< (≤-trans (s≤s a₁) (s≤s (s≤s m≤n) )) ≡⟨⟩ fromℕ< (s≤s (≤-trans a₁ (s≤s m≤n))) ≡⟨ lemma10 {suc (suc n)} (p3 x) {p6} {p2} ⟩ fromℕ< ( s≤s (fin<n {suc n} {x}) ) ≡⟨⟩ suc (fromℕ< (fin<n {suc n} {x} )) ≡⟨ cong suc (fromℕ<-toℕ x _ ) ⟩ suc x ∎ t7 = plist (pins {3} (n≤ 3)) ∷ plist (flip ( pins {3} (n≤ 3) )) ∷ plist ( pins {3} (n≤ 3) ∘ₚ flip ( pins {3} (n≤ 3))) ∷ [] -- t8 = {!!} open import logic open _∧_ perm1 : {perm : Permutation 1 1 } {q : Fin 1} → (perm ⟨$⟩ʳ q ≡ # 0) ∧ ((perm ⟨$⟩ˡ q ≡ # 0)) perm1 {p} {q} = ⟪ perm01 _ _ , perm00 _ _ ⟫ where perm01 : (x y : Fin 1) → (p ⟨$⟩ʳ x) ≡ y perm01 x y with p ⟨$⟩ʳ x perm01 zero zero | zero = refl perm00 : (x y : Fin 1) → (p ⟨$⟩ˡ x) ≡ y perm00 x y with p ⟨$⟩ˡ x perm00 zero zero | zero = refl ---- -- find insertion point of pins ---- p=0 : {n : ℕ } → (perm : Permutation (suc n) (suc n) ) → ((perm ∘ₚ flip (pins (toℕ≤pred[n] (perm ⟨$⟩ʳ (# 0))))) ⟨$⟩ˡ (# 0)) ≡ # 0 p=0 {zero} perm with ((perm ∘ₚ flip (pins (toℕ≤pred[n] (perm ⟨$⟩ʳ (# 0))))) ⟨$⟩ˡ (# 0)) ... | zero = refl p=0 {suc n} perm with perm ⟨$⟩ʳ (# 0) | inspect (_⟨$⟩ʳ_ perm ) (# 0)| toℕ≤pred[n] (perm ⟨$⟩ʳ (# 0)) | inspect toℕ≤pred[n] (perm ⟨$⟩ʳ (# 0)) ... | zero | record { eq = e} | m<n | _ = p001 where p001 : perm ⟨$⟩ˡ ( pins m<n ⟨$⟩ʳ zero) ≡ zero p001 = subst (λ k → perm ⟨$⟩ˡ k ≡ zero ) e (inverseˡ perm) ... | suc t | record { eq = e } | m<n | record { eq = e1 } = p002 where -- m<n : suc (toℕ t) ≤ suc n p002 : perm ⟨$⟩ˡ ( pins m<n ⟨$⟩ʳ zero) ≡ zero p002 = p005 zero (toℕ t) refl m<n refl where -- suc (toℕ t) ≤ suc n p003 : (s : Fin (suc (suc n))) → s ≡ (perm ⟨$⟩ʳ (# 0)) → perm ⟨$⟩ˡ s ≡ # 0 p003 s eq = subst (λ k → perm ⟨$⟩ˡ k ≡ zero ) (sym eq) (inverseˡ perm) p005 : (x : Fin (suc (suc n))) → (m : ℕ ) → x ≡ zero → (m≤n : suc m ≤ suc n ) → m ≡ toℕ t → perm ⟨$⟩ˡ ( pins m≤n ⟨$⟩ʳ zero) ≡ zero p005 zero m eq (s≤s m≤n) meq = p004 where p004 : perm ⟨$⟩ˡ (fromℕ< (s≤s (s≤s m≤n))) ≡ zero p004 = p003 (fromℕ< (s≤s (s≤s m≤n))) ( begin fromℕ< (s≤s (s≤s m≤n)) ≡⟨ lemma10 {suc (suc n)} (cong suc meq) {s≤s (s≤s m≤n)} {subst (λ k → suc k < suc (suc n)) meq (s≤s (s≤s m≤n)) } ⟩ fromℕ< (subst (λ k → suc k < suc (suc n)) meq (s≤s (s≤s m≤n)) ) ≡⟨ fromℕ<-toℕ {suc (suc n)} (suc t) (subst (λ k → suc k < suc (suc n)) meq (s≤s (s≤s m≤n)) ) ⟩ suc t ≡⟨ sym e ⟩ (perm ⟨$⟩ʳ (# 0)) ∎ ) ---- -- other elements are preserved in pins ---- px=x : {n : ℕ } → (x : Fin (suc n)) → pins ( toℕ≤pred[n] x ) ⟨$⟩ʳ (# 0) ≡ x px=x {n} zero = refl px=x {suc n} (suc x) = p001 where p002 : fromℕ< (s≤s (toℕ≤pred[n] x)) ≡ x p002 = fromℕ<-toℕ x (s≤s (toℕ≤pred[n] x)) p001 : (pins (toℕ≤pred[n] (suc x)) ⟨$⟩ʳ (# 0)) ≡ suc x p001 with <-cmp 0 ((toℕ x)) ... | tri< a ¬b ¬c = cong suc p002 ... | tri≈ ¬a b ¬c = cong suc p002 -- pp : {n : ℕ } → (perm : Permutation (suc n) (suc n) ) → Fin (suc n) -- pp perm → (( perm ∘ₚ flip (pins (toℕ≤pred[n] (perm ⟨$⟩ʳ (# 0))))) ⟨$⟩ˡ (# 0)) plist2 : {n : ℕ} → Permutation (suc n) (suc n) → (i : ℕ ) → i < suc n → List ℕ plist2 {n} perm zero _ = toℕ ( perm ⟨$⟩ʳ (fromℕ< {zero} (s≤s z≤n))) ∷ [] plist2 {n} perm (suc i) (s≤s lt) = toℕ ( perm ⟨$⟩ʳ (fromℕ< (s≤s lt))) ∷ plist2 perm i (<-trans lt a<sa) plist0 : {n : ℕ} → Permutation n n → List ℕ plist0 {0} perm = [] plist0 {suc n} perm = plist2 perm n a<sa open _=p=_ -- -- plist cong -- ←pleq : {n : ℕ} → (x y : Permutation n n ) → x =p= y → plist0 x ≡ plist0 y ←pleq {zero} x y eq = refl ←pleq {suc n} x y eq = ←pleq1 n a<sa where ←pleq1 : (i : ℕ ) → (i<sn : i < suc n ) → plist2 x i i<sn ≡ plist2 y i i<sn ←pleq1 zero _ = cong ( λ k → toℕ k ∷ [] ) ( peq eq (fromℕ< {zero} (s≤s z≤n))) ←pleq1 (suc i) (s≤s lt) = cong₂ ( λ j k → toℕ j ∷ k ) ( peq eq (fromℕ< (s≤s lt))) ( ←pleq1 i (<-trans lt a<sa) ) headeq : {A : Set } → {x y : A } → {xt yt : List A } → (x ∷ xt) ≡ (y ∷ yt) → x ≡ y headeq refl = refl taileq : {A : Set } → {x y : A } → {xt yt : List A } → (x ∷ xt) ≡ (y ∷ yt) → xt ≡ yt taileq refl = refl -- -- plist injection / equalizer -- -- if plist0 of two perm looks the same, the permutations are the same -- pleq : {n : ℕ} → (x y : Permutation n n ) → plist0 x ≡ plist0 y → x =p= y pleq {0} x y refl = record { peq = λ q → pleq0 q } where pleq0 : (q : Fin 0 ) → (x ⟨$⟩ʳ q) ≡ (y ⟨$⟩ʳ q) pleq0 () pleq {suc n} x y eq = record { peq = λ q → pleq1 n a<sa eq q fin<n } where pleq1 : (i : ℕ ) → (i<sn : i < suc n ) → plist2 x i i<sn ≡ plist2 y i i<sn → (q : Fin (suc n)) → toℕ q < suc i → x ⟨$⟩ʳ q ≡ y ⟨$⟩ʳ q pleq1 zero i<sn eq q q<i with <-cmp (toℕ q) zero ... | tri< () ¬b ¬c ... | tri> ¬a ¬b c = ⊥-elim (nat-≤> c q<i ) ... | tri≈ ¬a b ¬c = begin x ⟨$⟩ʳ q ≡⟨ cong ( λ k → x ⟨$⟩ʳ k ) (toℕ-injective b )⟩ x ⟨$⟩ʳ zero ≡⟨ toℕ-injective (headeq eq) ⟩ y ⟨$⟩ʳ zero ≡⟨ cong ( λ k → y ⟨$⟩ʳ k ) (sym (toℕ-injective b )) ⟩ y ⟨$⟩ʳ q ∎ pleq1 (suc i) (s≤s i<sn) eq q q<i with <-cmp (toℕ q) (suc i) ... | tri< a ¬b ¬c = pleq1 i (<-trans i<sn a<sa ) (taileq eq) q a ... | tri> ¬a ¬b c = ⊥-elim (nat-≤> c q<i ) ... | tri≈ ¬a b ¬c = begin x ⟨$⟩ʳ q ≡⟨ cong (λ k → x ⟨$⟩ʳ k) (pleq3 b) ⟩ x ⟨$⟩ʳ (suc (fromℕ< i<sn)) ≡⟨ toℕ-injective pleq2 ⟩ y ⟨$⟩ʳ (suc (fromℕ< i<sn)) ≡⟨ cong (λ k → y ⟨$⟩ʳ k) (sym (pleq3 b)) ⟩ y ⟨$⟩ʳ q ∎ where pleq3 : toℕ q ≡ suc i → q ≡ suc (fromℕ< i<sn) pleq3 tq=si = toℕ-injective ( begin toℕ q ≡⟨ b ⟩ suc i ≡⟨ sym (toℕ-fromℕ< (s≤s i<sn)) ⟩ toℕ (fromℕ< (s≤s i<sn)) ≡⟨⟩ toℕ (suc (fromℕ< i<sn)) ∎ ) pleq2 : toℕ ( x ⟨$⟩ʳ (suc (fromℕ< i<sn)) ) ≡ toℕ ( y ⟨$⟩ʳ (suc (fromℕ< i<sn)) ) pleq2 = headeq eq is-=p= : {n : ℕ} → (x y : Permutation n n ) → Dec (x =p= y ) is-=p= {zero} x y = yes record { peq = λ () } is-=p= {suc n} x y with ℕL-eq? (plist0 x ) ( plist0 y ) ... | yes t = yes (pleq x y t) ... | no t = no ( contra-position (←pleq x y) t ) pprep-cong : {n : ℕ} → {x y : Permutation n n } → x =p= y → pprep x =p= pprep y pprep-cong {n} {x} {y} x=y = record { peq = pprep-cong1 } where pprep-cong1 : (q : Fin (suc n)) → (pprep x ⟨$⟩ʳ q) ≡ (pprep y ⟨$⟩ʳ q) pprep-cong1 zero = refl pprep-cong1 (suc q) = begin pprep x ⟨$⟩ʳ suc q ≡⟨⟩ suc ( x ⟨$⟩ʳ q ) ≡⟨ cong ( λ k → suc k ) ( peq x=y q ) ⟩ suc ( y ⟨$⟩ʳ q ) ≡⟨⟩ pprep y ⟨$⟩ʳ suc q ∎ pprep-dist : {n : ℕ} → {x y : Permutation n n } → pprep (x ∘ₚ y) =p= (pprep x ∘ₚ pprep y) pprep-dist {n} {x} {y} = record { peq = pprep-dist1 } where pprep-dist1 : (q : Fin (suc n)) → (pprep (x ∘ₚ y) ⟨$⟩ʳ q) ≡ ((pprep x ∘ₚ pprep y) ⟨$⟩ʳ q) pprep-dist1 zero = refl pprep-dist1 (suc q) = cong ( λ k → suc k ) refl pswap-cong : {n : ℕ} → {x y : Permutation n n } → x =p= y → pswap x =p= pswap y pswap-cong {n} {x} {y} x=y = record { peq = pswap-cong1 } where pswap-cong1 : (q : Fin (suc (suc n))) → (pswap x ⟨$⟩ʳ q) ≡ (pswap y ⟨$⟩ʳ q) pswap-cong1 zero = refl pswap-cong1 (suc zero) = refl pswap-cong1 (suc (suc q)) = begin pswap x ⟨$⟩ʳ suc (suc q) ≡⟨⟩ suc (suc (x ⟨$⟩ʳ q)) ≡⟨ cong ( λ k → suc (suc k) ) ( peq x=y q ) ⟩ suc (suc (y ⟨$⟩ʳ q)) ≡⟨⟩ pswap y ⟨$⟩ʳ suc (suc q) ∎ pswap-dist : {n : ℕ} → {x y : Permutation n n } → pprep (pprep (x ∘ₚ y)) =p= (pswap x ∘ₚ pswap y) pswap-dist {n} {x} {y} = record { peq = pswap-dist1 } where pswap-dist1 : (q : Fin (suc (suc n))) → ((pprep (pprep (x ∘ₚ y))) ⟨$⟩ʳ q) ≡ ((pswap x ∘ₚ pswap y) ⟨$⟩ʳ q) pswap-dist1 zero = refl pswap-dist1 (suc zero) = refl pswap-dist1 (suc (suc q)) = cong ( λ k → suc (suc k) ) refl shlem→ : {n : ℕ} → (perm : Permutation (suc n) (suc n) ) → (p0=0 : perm ⟨$⟩ˡ (# 0) ≡ # 0 ) → (x : Fin (suc n) ) → perm ⟨$⟩ˡ x ≡ zero → x ≡ zero shlem→ perm p0=0 x px=0 = begin x ≡⟨ sym ( inverseʳ perm ) ⟩ perm ⟨$⟩ʳ ( perm ⟨$⟩ˡ x) ≡⟨ cong (λ k → perm ⟨$⟩ʳ k ) px=0 ⟩ perm ⟨$⟩ʳ zero ≡⟨ cong (λ k → perm ⟨$⟩ʳ k ) (sym p0=0) ⟩ perm ⟨$⟩ʳ ( perm ⟨$⟩ˡ zero) ≡⟨ inverseʳ perm ⟩ zero ∎ shlem← : {n : ℕ} → (perm : Permutation (suc n) (suc n) ) → (p0=0 : perm ⟨$⟩ˡ (# 0) ≡ # 0 ) → (x : Fin (suc n)) → perm ⟨$⟩ʳ x ≡ zero → x ≡ zero shlem← perm p0=0 x px=0 = begin x ≡⟨ sym (inverseˡ perm ) ⟩ perm ⟨$⟩ˡ ( perm ⟨$⟩ʳ x ) ≡⟨ cong (λ k → perm ⟨$⟩ˡ k ) px=0 ⟩ perm ⟨$⟩ˡ zero ≡⟨ p0=0 ⟩ zero ∎ sh2 : {n : ℕ} → (perm : Permutation (suc n) (suc n) ) → (p0=0 : perm ⟨$⟩ˡ (# 0) ≡ # 0 ) → {x : Fin n} → ¬ perm ⟨$⟩ˡ (suc x) ≡ zero sh2 perm p0=0 {x} eq with shlem→ perm p0=0 (suc x) eq sh2 perm p0=0 {x} eq | () sh1 : {n : ℕ} → (perm : Permutation (suc n) (suc n) ) → (p0=0 : perm ⟨$⟩ˡ (# 0) ≡ # 0 ) → {x : Fin n} → ¬ perm ⟨$⟩ʳ (suc x) ≡ zero sh1 perm p0=0 {x} eq with shlem← perm p0=0 (suc x) eq sh1 perm p0=0 {x} eq | () -- 0 ∷ 1 ∷ 2 ∷ 3 ∷ [] → 0 ∷ 1 ∷ 2 ∷ [] shrink : {n : ℕ} → (perm : Permutation (suc n) (suc n) ) → perm ⟨$⟩ˡ (# 0) ≡ # 0 → Permutation n n shrink {n} perm p0=0 = permutation p→ p← record { left-inverse-of = piso→ ; right-inverse-of = piso← } where p→ : Fin n → Fin n p→ x with perm ⟨$⟩ʳ (suc x) | inspect (_⟨$⟩ʳ_ perm ) (suc x) p→ x | zero | record { eq = e } = ⊥-elim ( sh1 perm p0=0 {x} e ) p→ x | suc t | _ = t p← : Fin n → Fin n p← x with perm ⟨$⟩ˡ (suc x) | inspect (_⟨$⟩ˡ_ perm ) (suc x) p← x | zero | record { eq = e } = ⊥-elim ( sh2 perm p0=0 {x} e ) p← x | suc t | _ = t piso← : (x : Fin n ) → p→ ( p← x ) ≡ x piso← x with perm ⟨$⟩ˡ (suc x) | inspect (_⟨$⟩ˡ_ perm ) (suc x) piso← x | zero | record { eq = e } = ⊥-elim ( sh2 perm p0=0 {x} e ) piso← x | suc t | _ with perm ⟨$⟩ʳ (suc t) | inspect (_⟨$⟩ʳ_ perm ) (suc t) piso← x | suc t | _ | zero | record { eq = e } = ⊥-elim ( sh1 perm p0=0 e ) piso← x | suc t | record { eq = e0 } | suc t1 | record { eq = e1 } = begin t1 ≡⟨ plem0 plem1 ⟩ x ∎ where open ≡-Reasoning plem0 : suc t1 ≡ suc x → t1 ≡ x plem0 refl = refl plem1 : suc t1 ≡ suc x plem1 = begin suc t1 ≡⟨ sym e1 ⟩ Inverse.to perm Π.⟨$⟩ suc t ≡⟨ cong (λ k → Inverse.to perm Π.⟨$⟩ k ) (sym e0) ⟩ Inverse.to perm Π.⟨$⟩ ( Inverse.from perm Π.⟨$⟩ suc x ) ≡⟨ inverseʳ perm ⟩ suc x ∎ piso→ : (x : Fin n ) → p← ( p→ x ) ≡ x piso→ x with perm ⟨$⟩ʳ (suc x) | inspect (_⟨$⟩ʳ_ perm ) (suc x) piso→ x | zero | record { eq = e } = ⊥-elim ( sh1 perm p0=0 {x} e ) piso→ x | suc t | _ with perm ⟨$⟩ˡ (suc t) | inspect (_⟨$⟩ˡ_ perm ) (suc t) piso→ x | suc t | _ | zero | record { eq = e } = ⊥-elim ( sh2 perm p0=0 e ) piso→ x | suc t | record { eq = e0 } | suc t1 | record { eq = e1 } = begin t1 ≡⟨ plem2 plem3 ⟩ x ∎ where plem2 : suc t1 ≡ suc x → t1 ≡ x plem2 refl = refl plem3 : suc t1 ≡ suc x plem3 = begin suc t1 ≡⟨ sym e1 ⟩ Inverse.from perm Π.⟨$⟩ suc t ≡⟨ cong (λ k → Inverse.from perm Π.⟨$⟩ k ) (sym e0 ) ⟩ Inverse.from perm Π.⟨$⟩ ( Inverse.to perm Π.⟨$⟩ suc x ) ≡⟨ inverseˡ perm ⟩ suc x ∎ shrink-iso : { n : ℕ } → {perm : Permutation n n} → shrink (pprep perm) refl =p= perm shrink-iso {n} {perm} = record { peq = λ q → refl } shrink-iso2 : { n : ℕ } → {perm : Permutation (suc n) (suc n)} → (p=0 : perm ⟨$⟩ˡ (# 0) ≡ # 0) → pprep (shrink perm p=0) =p= perm shrink-iso2 {n} {perm} p=0 = record { peq = s001 } where s001 : (q : Fin (suc n)) → (pprep (shrink perm p=0) ⟨$⟩ʳ q) ≡ perm ⟨$⟩ʳ q s001 zero = begin zero ≡⟨ sym ( inverseʳ perm ) ⟩ perm ⟨$⟩ʳ ( perm ⟨$⟩ˡ zero ) ≡⟨ cong (λ k → perm ⟨$⟩ʳ k ) p=0 ⟩ perm ⟨$⟩ʳ zero ∎ s001 (suc q) with perm ⟨$⟩ʳ (suc q) | inspect (_⟨$⟩ʳ_ perm ) (suc q) ... | zero | record {eq = e} = ⊥-elim (sh1 perm p=0 {q} e) ... | suc t | e = refl shrink-cong : { n : ℕ } → {x y : Permutation (suc n) (suc n)} → x =p= y → (x=0 : x ⟨$⟩ˡ (# 0) ≡ # 0 ) → (y=0 : y ⟨$⟩ˡ (# 0) ≡ # 0 ) → shrink x x=0 =p= shrink y y=0 shrink-cong {n} {x} {y} x=y x=0 y=0 = record { peq = p002 } where p002 : (q : Fin n) → (shrink x x=0 ⟨$⟩ʳ q) ≡ (shrink y y=0 ⟨$⟩ʳ q) p002 q with x ⟨$⟩ʳ (suc q) | inspect (_⟨$⟩ʳ_ x ) (suc q) | y ⟨$⟩ʳ (suc q) | inspect (_⟨$⟩ʳ_ y ) (suc q) p002 q | zero | record { eq = ex } | zero | ey = ⊥-elim ( sh1 x x=0 ex ) p002 q | zero | record { eq = ex } | suc py | ey = ⊥-elim ( sh1 x x=0 ex ) p002 q | suc px | ex | zero | record { eq = ey } = ⊥-elim ( sh1 y y=0 ey ) p002 q | suc px | record { eq = ex } | suc py | record { eq = ey } = p003 ( begin suc px ≡⟨ sym ex ⟩ x ⟨$⟩ʳ (suc q) ≡⟨ peq x=y (suc q) ⟩ y ⟨$⟩ʳ (suc q) ≡⟨ ey ⟩ suc py ∎ ) where p003 : suc px ≡ suc py → px ≡ py p003 refl = refl open import FLutil FL→perm : {n : ℕ } → FL n → Permutation n n FL→perm f0 = pid FL→perm (x :: fl) = pprep (FL→perm fl) ∘ₚ pins ( toℕ≤pred[n] x ) t40 = (# 2) :: ( (# 1) :: (( # 0 ) :: f0 )) t4 = FL→perm ((# 2) :: t40 ) -- t1 = plist (shrink (pid {3} ∘ₚ (pins (n≤ 1))) refl) t2 = plist ((pid {5} ) ∘ₚ transpose (# 2) (# 4)) ∷ plist (pid {5} ∘ₚ reverse ) ∷ [] t3 = plist (FL→perm t40) -- ∷ plist (pprep (FL→perm t40)) -- ∷ plist ( pprep (FL→perm t40) ∘ₚ pins ( n≤ 0 {3} )) -- ∷ plist ( pprep (FL→perm t40 )∘ₚ pins ( n≤ 1 {2} )) -- ∷ plist ( pprep (FL→perm t40 )∘ₚ pins ( n≤ 2 {1} )) -- ∷ plist ( pprep (FL→perm t40 )∘ₚ pins ( n≤ 3 {0} )) ∷ plist ( FL→perm ((# 0) :: t40)) -- (0 ∷ 1 ∷ 2 ∷ []) ∷ ∷ plist ( FL→perm ((# 1) :: t40)) -- (0 ∷ 2 ∷ 1 ∷ []) ∷ ∷ plist ( FL→perm ((# 2) :: t40)) -- (1 ∷ 0 ∷ 2 ∷ []) ∷ ∷ plist ( FL→perm ((# 3) :: t40)) -- (2 ∷ 0 ∷ 1 ∷ []) ∷ -- ∷ plist ( FL→perm ((# 3) :: ((# 2) :: ( (# 0) :: (( # 0 ) :: f0 )) ))) -- (1 ∷ 2 ∷ 0 ∷ []) ∷ -- ∷ plist ( FL→perm ((# 3) :: ((# 2) :: ( (# 1) :: (( # 0 ) :: f0 )) ))) -- (2 ∷ 1 ∷ 0 ∷ []) ∷ -- ∷ plist ( (flip (FL→perm ((# 3) :: ((# 1) :: ( (# 0) :: (( # 0 ) :: f0 )) ))))) -- ∷ plist ( (flip (FL→perm ((# 3) :: ((# 1) :: ( (# 0) :: (( # 0 ) :: f0 )) ))) ∘ₚ (FL→perm ((# 3) :: (((# 1) :: ( (# 0) :: (( # 0 ) :: f0 )) )))) )) ∷ [] -- FL→plist-iso : {n : ℕ} → (f : FL n ) → plist→FL (FL→plist f ) ≡ f -- FL→plist-inject : {n : ℕ} → (f g : FL n ) → FL→plist f ≡ FL→plist g → f ≡ g perm→FL : {n : ℕ } → Permutation n n → FL n perm→FL {zero} perm = f0 perm→FL {suc n} perm = (perm ⟨$⟩ʳ (# 0)) :: perm→FL (shrink (perm ∘ₚ flip (pins (toℕ≤pred[n] (perm ⟨$⟩ʳ (# 0))))) (p=0 perm) ) ---FL→perm : {n : ℕ } → FL n → Permutation n n ---FL→perm x = plist→perm ( FL→plis x) -- perm→FL : {n : ℕ } → Permutation n n → FL n -- perm→FL p = plist→FL (plist p) -- pcong-pF : {n : ℕ } → {x y : Permutation n n} → x =p= y → perm→FL x ≡ perm→FL y -- pcong-pF {n} {x} {y} x=y = FL→plist-inject (subst ... (pleq← eq)) (perm→FL x) (perm→FL y) -- FL→iso : {n : ℕ } → (fl : FL n ) → perm→FL ( FL→perm fl ) ≡ fl -- FL→iso = -- pcong-Fp : {n : ℕ } → {x y : FL n} → x ≡ y → FL→perm x =p= FL→perm y -- FL←iso : {n : ℕ } → (perm : Permutation n n ) → FL→perm ( perm→FL perm ) =p= perm _p<_ : {n : ℕ } ( x y : Permutation n n ) → Set x p< y = perm→FL x f< perm→FL y pcong-pF : {n : ℕ } → {x y : Permutation n n} → x =p= y → perm→FL x ≡ perm→FL y pcong-pF {zero} eq = refl pcong-pF {suc n} {x} {y} eq = cong₂ (λ j k → j :: k ) ( peq eq (# 0)) (pcong-pF (shrink-cong (presp eq p001 ) (p=0 x) (p=0 y))) where p002 : x ⟨$⟩ʳ (# 0) ≡ y ⟨$⟩ʳ (# 0) p002 = peq eq (# 0) p001 : flip (pins (toℕ≤pred[n] (x ⟨$⟩ʳ (# 0)))) =p= flip (pins (toℕ≤pred[n] (y ⟨$⟩ʳ (# 0)))) p001 = subst ( λ k → flip (pins (toℕ≤pred[n] (x ⟨$⟩ʳ (# 0)))) =p= flip (pins (toℕ≤pred[n] k ))) p002 prefl -- t5 = plist t4 ∷ plist ( t4 ∘ₚ flip (pins ( n≤ 3 ) )) t5 = plist (t4) ∷ plist (flip t4) ∷ ( toℕ (t4 ⟨$⟩ˡ fromℕ< a<sa) ∷ [] ) ∷ ( toℕ (t4 ⟨$⟩ʳ (# 0)) ∷ [] ) -- ∷ plist ( t4 ∘ₚ flip (pins ( n≤ 1 ) )) ∷ plist (remove (# 0) t4 ) ∷ plist ( FL→perm t40 ) ∷ [] t6 = perm→FL t4 FL→iso : {n : ℕ } → (fl : FL n ) → perm→FL ( FL→perm fl ) ≡ fl FL→iso f0 = refl FL→iso {suc n} (x :: fl) = cong₂ ( λ j k → j :: k ) f001 f002 where perm = pprep (FL→perm fl) ∘ₚ pins ( toℕ≤pred[n] x ) f001 : perm ⟨$⟩ʳ (# 0) ≡ x f001 = begin (pprep (FL→perm fl) ∘ₚ pins ( toℕ≤pred[n] x )) ⟨$⟩ʳ (# 0) ≡⟨⟩ pins ( toℕ≤pred[n] x ) ⟨$⟩ʳ (# 0) ≡⟨ px=x x ⟩ x ∎ x=0 : (perm ∘ₚ flip (pins (toℕ≤pred[n] x))) ⟨$⟩ˡ (# 0) ≡ # 0 x=0 = subst ( λ k → (perm ∘ₚ flip (pins (toℕ≤pred[n] k))) ⟨$⟩ˡ (# 0) ≡ # 0 ) f001 (p=0 perm) x=0' : (pprep (FL→perm fl) ∘ₚ pid) ⟨$⟩ˡ (# 0) ≡ # 0 x=0' = refl f003 : (q : Fin (suc n)) → ((perm ∘ₚ flip (pins (toℕ≤pred[n] (perm ⟨$⟩ʳ (# 0))))) ⟨$⟩ʳ q) ≡ ((perm ∘ₚ flip (pins (toℕ≤pred[n] x))) ⟨$⟩ʳ q) f003 q = cong (λ k → (perm ∘ₚ flip (pins (toℕ≤pred[n] k))) ⟨$⟩ʳ q ) f001 f002 : perm→FL (shrink (perm ∘ₚ flip (pins (toℕ≤pred[n] (perm ⟨$⟩ʳ (# 0))))) (p=0 perm) ) ≡ fl f002 = begin perm→FL (shrink (perm ∘ₚ flip (pins (toℕ≤pred[n] (perm ⟨$⟩ʳ (# 0))))) (p=0 perm) ) ≡⟨ pcong-pF (shrink-cong {n} {perm ∘ₚ flip (pins (toℕ≤pred[n] (perm ⟨$⟩ʳ (# 0))))} {perm ∘ₚ flip (pins (toℕ≤pred[n] x))} record {peq = f003 } (p=0 perm) x=0) ⟩ perm→FL (shrink (perm ∘ₚ flip (pins (toℕ≤pred[n] x))) x=0 ) ≡⟨⟩ perm→FL (shrink ((pprep (FL→perm fl) ∘ₚ pins ( toℕ≤pred[n] x )) ∘ₚ flip (pins (toℕ≤pred[n] x))) x=0 ) ≡⟨ pcong-pF (shrink-cong (passoc (pprep (FL→perm fl)) (pins ( toℕ≤pred[n] x )) (flip (pins (toℕ≤pred[n] x))) ) x=0 x=0) ⟩ perm→FL (shrink (pprep (FL→perm fl) ∘ₚ (pins ( toℕ≤pred[n] x ) ∘ₚ flip (pins (toℕ≤pred[n] x)))) x=0 ) ≡⟨ pcong-pF (shrink-cong {n} {pprep (FL→perm fl) ∘ₚ (pins ( toℕ≤pred[n] x ) ∘ₚ flip (pins (toℕ≤pred[n] x)))} {pprep (FL→perm fl) ∘ₚ pid} ( presp {suc n} {pprep (FL→perm fl) } {_} {(pins ( toℕ≤pred[n] x ) ∘ₚ flip (pins (toℕ≤pred[n] x)))} {pid} prefl record { peq = λ q → inverseˡ (pins ( toℕ≤pred[n] x )) } ) x=0 x=0') ⟩ perm→FL (shrink (pprep (FL→perm fl) ∘ₚ pid) x=0' ) ≡⟨ pcong-pF (shrink-cong {n} {pprep (FL→perm fl) ∘ₚ pid} {pprep (FL→perm fl)} record {peq = λ q → refl } x=0' x=0') ⟩ -- prefl won't work perm→FL (shrink (pprep (FL→perm fl)) x=0' ) ≡⟨ pcong-pF shrink-iso ⟩ perm→FL ( FL→perm fl ) ≡⟨ FL→iso fl ⟩ fl ∎ pcong-Fp : {n : ℕ } → {x y : FL n} → x ≡ y → FL→perm x =p= FL→perm y pcong-Fp {n} {x} {x} refl = prefl FL←iso : {n : ℕ } → (perm : Permutation n n ) → FL→perm ( perm→FL perm ) =p= perm FL←iso {0} perm = record { peq = λ () } FL←iso {suc n} perm = record { peq = λ q → ( begin FL→perm ( perm→FL perm ) ⟨$⟩ʳ q ≡⟨⟩ (pprep (FL→perm (perm→FL (shrink (perm ∘ₚ flip (pins (toℕ≤pred[n] (perm ⟨$⟩ʳ (# 0))))) (p=0 perm) ))) ∘ₚ pins ( toℕ≤pred[n] (perm ⟨$⟩ʳ (# 0)) ) ) ⟨$⟩ʳ q ≡⟨ peq (presp {suc n} {_} {_} {pins ( toℕ≤pred[n] (perm ⟨$⟩ʳ (# 0)))} (pprep-cong {n} {FL→perm (perm→FL (shrink (perm ∘ₚ flip (pins (toℕ≤pred[n] (perm ⟨$⟩ʳ (# 0))))) (p=0 perm) ))} (FL←iso _ ) ) prefl ) q ⟩ (pprep (shrink (perm ∘ₚ flip (pins (toℕ≤pred[n] (perm ⟨$⟩ʳ (# 0))))) (p=0 perm)) ∘ₚ pins ( toℕ≤pred[n] (perm ⟨$⟩ʳ (# 0)) )) ⟨$⟩ʳ q ≡⟨ peq (presp {suc n} {pprep (shrink (perm ∘ₚ flip (pins (toℕ≤pred[n] (perm ⟨$⟩ʳ (# 0))))) (p=0 perm))} {perm ∘ₚ flip (pins (toℕ≤pred[n] (perm ⟨$⟩ʳ (# 0))))} {pins ( toℕ≤pred[n] (perm ⟨$⟩ʳ (# 0)) )} (shrink-iso2 (p=0 perm)) prefl) q ⟩ ((perm ∘ₚ flip (pins (toℕ≤pred[n] (perm ⟨$⟩ʳ (# 0))))) ∘ₚ pins ( toℕ≤pred[n] (perm ⟨$⟩ʳ (# 0)) )) ⟨$⟩ʳ q ≡⟨ peq (presp {suc n} {perm} {_} {flip (pins (toℕ≤pred[n] (perm ⟨$⟩ʳ (# 0)))) ∘ₚ pins ( toℕ≤pred[n] (perm ⟨$⟩ʳ (# 0)))} {pid} prefl record { peq = λ q → inverseʳ (pins (toℕ≤pred[n] (perm ⟨$⟩ʳ (# 0)))) }) q ⟩ ( perm ∘ₚ pid ) ⟨$⟩ʳ q ≡⟨⟩ perm ⟨$⟩ʳ q ∎ ) } FL-inject : {n : ℕ } → {g h : Permutation n n } → perm→FL g ≡ perm→FL h → g =p= h FL-inject {n} {g} {h} g=h = record { peq = λ q → ( begin g ⟨$⟩ʳ q ≡⟨ peq (psym (FL←iso g )) q ⟩ ( FL→perm (perm→FL g) ) ⟨$⟩ʳ q ≡⟨ cong ( λ k → FL→perm k ⟨$⟩ʳ q ) g=h ⟩ ( FL→perm (perm→FL h) ) ⟨$⟩ʳ q ≡⟨ peq (FL←iso h) q ⟩ h ⟨$⟩ʳ q ∎ ) } FLpid : {n : ℕ} → (x : Permutation n n) → perm→FL x ≡ FL0 → FL→perm FL0 =p= pid → x =p= pid FLpid x eq p0id = ptrans pf2 (ptrans pf0 p0id ) where pf2 : x =p= FL→perm (perm→FL x) pf2 = psym (FL←iso x) pf0 : FL→perm (perm→FL x) =p= FL→perm FL0 pf0 = pcong-Fp eq pFL0 : {n : ℕ } → FL0 {n} ≡ perm→FL pid pFL0 {zero} = refl pFL0 {suc n} = cong (λ k → zero :: k ) pFL0