module Data.Nat.Properties where
open import Relation.Binary
open import Function
open import Algebra
import Algebra.RingSolver.Simple as Solver
import Algebra.RingSolver.AlmostCommutativeRing as ACR
open import Algebra.Structures
open import Data.Nat as Nat
open import Data.Product
open import Data.Sum
open import Relation.Nullary
open import Relation.Nullary.Negation using (contradiction)
open import Relation.Binary.PropositionalEquality
open import Algebra.FunctionProperties (_≡_ {A = ℕ})
hiding (LeftCancellative; RightCancellative; Cancellative)
open import Algebra.FunctionProperties
using (LeftCancellative; RightCancellative; Cancellative)
open import Algebra.FunctionProperties.Consequences (setoid ℕ)
open import Algebra.Morphism
open ≡-Reasoning
suc-injective : ∀ {m n} → suc m ≡ suc n → m ≡ n
suc-injective refl = refl
≡-isDecEquivalence : IsDecEquivalence (_≡_ {A = ℕ})
≡-isDecEquivalence = record
{ isEquivalence = isEquivalence
; _≟_ = _≟_
}
≡-decSetoid : DecSetoid _ _
≡-decSetoid = record
{ Carrier = ℕ
; _≈_ = _≡_
; isDecEquivalence = ≡-isDecEquivalence
}
≤-reflexive : _≡_ ⇒ _≤_
≤-reflexive {zero} refl = z≤n
≤-reflexive {suc m} refl = s≤s (≤-reflexive refl)
≤-refl : Reflexive _≤_
≤-refl = ≤-reflexive refl
≤-antisym : Antisymmetric _≡_ _≤_
≤-antisym z≤n z≤n = refl
≤-antisym (s≤s m≤n) (s≤s n≤m) with ≤-antisym m≤n n≤m
... | refl = refl
≤-trans : Transitive _≤_
≤-trans z≤n _ = z≤n
≤-trans (s≤s m≤n) (s≤s n≤o) = s≤s (≤-trans m≤n n≤o)
≤-total : Total _≤_
≤-total zero _ = inj₁ z≤n
≤-total _ zero = inj₂ z≤n
≤-total (suc m) (suc n) with ≤-total m n
... | inj₁ m≤n = inj₁ (s≤s m≤n)
... | inj₂ n≤m = inj₂ (s≤s n≤m)
≤-isPreorder : IsPreorder _≡_ _≤_
≤-isPreorder = record
{ isEquivalence = isEquivalence
; reflexive = ≤-reflexive
; trans = ≤-trans
}
≤-preorder : Preorder _ _ _
≤-preorder = record
{ isPreorder = ≤-isPreorder
}
≤-isPartialOrder : IsPartialOrder _≡_ _≤_
≤-isPartialOrder = record
{ isPreorder = ≤-isPreorder
; antisym = ≤-antisym
}
≤-isTotalOrder : IsTotalOrder _≡_ _≤_
≤-isTotalOrder = record
{ isPartialOrder = ≤-isPartialOrder
; total = ≤-total
}
≤-totalOrder : TotalOrder _ _ _
≤-totalOrder = record
{ isTotalOrder = ≤-isTotalOrder
}
≤-isDecTotalOrder : IsDecTotalOrder _≡_ _≤_
≤-isDecTotalOrder = record
{ isTotalOrder = ≤-isTotalOrder
; _≟_ = _≟_
; _≤?_ = _≤?_
}
≤-decTotalOrder : DecTotalOrder _ _ _
≤-decTotalOrder = record
{ isDecTotalOrder = ≤-isDecTotalOrder
}
≤-step : ∀ {m n} → m ≤ n → m ≤ 1 + n
≤-step z≤n = z≤n
≤-step (s≤s m≤n) = s≤s (≤-step m≤n)
n≤1+n : ∀ n → n ≤ 1 + n
n≤1+n _ = ≤-step ≤-refl
1+n≰n : ∀ {n} → ¬ 1 + n ≤ n
1+n≰n (s≤s le) = 1+n≰n le
pred-mono : pred Preserves _≤_ ⟶ _≤_
pred-mono z≤n = z≤n
pred-mono (s≤s le) = le
≤pred⇒≤ : ∀ {m n} → m ≤ pred n → m ≤ n
≤pred⇒≤ {m} {zero} le = le
≤pred⇒≤ {m} {suc n} le = ≤-step le
≤⇒pred≤ : ∀ {m n} → m ≤ n → pred m ≤ n
≤⇒pred≤ {zero} le = le
≤⇒pred≤ {suc m} le = ≤-trans (n≤1+n m) le
_<?_ : Decidable _<_
x <? y = suc x ≤? y
<-irrefl : Irreflexive _≡_ _<_
<-irrefl refl (s≤s n<n) = <-irrefl refl n<n
<-asym : Asymmetric _<_
<-asym (s≤s n<m) (s≤s m<n) = <-asym n<m m<n
<-trans : Transitive _<_
<-trans (s≤s i≤j) (s≤s j<k) = s≤s (≤-trans i≤j (≤⇒pred≤ j<k))
<-transʳ : Trans _≤_ _<_ _<_
<-transʳ m≤n (s≤s n≤o) = s≤s (≤-trans m≤n n≤o)
<-transˡ : Trans _<_ _≤_ _<_
<-transˡ (s≤s m≤n) (s≤s n≤o) = s≤s (≤-trans m≤n n≤o)
<-cmp : Trichotomous _≡_ _<_
<-cmp zero zero = tri≈ (λ()) refl (λ())
<-cmp zero (suc n) = tri< (s≤s z≤n) (λ()) (λ())
<-cmp (suc m) zero = tri> (λ()) (λ()) (s≤s z≤n)
<-cmp (suc m) (suc n) with <-cmp m n
... | tri< ≤ ≢ ≱ = tri< (s≤s ≤) (≢ ∘ suc-injective) (≱ ∘ ≤-pred)
... | tri≈ ≰ ≡ ≱ = tri≈ (≰ ∘ ≤-pred) (cong suc ≡) (≱ ∘ ≤-pred)
... | tri> ≰ ≢ ≥ = tri> (≰ ∘ ≤-pred) (≢ ∘ suc-injective) (s≤s ≥)
<-isStrictTotalOrder : IsStrictTotalOrder _≡_ _<_
<-isStrictTotalOrder = record
{ isEquivalence = isEquivalence
; trans = <-trans
; compare = <-cmp
}
<-strictTotalOrder : StrictTotalOrder _ _ _
<-strictTotalOrder = record
{ isStrictTotalOrder = <-isStrictTotalOrder
}
<⇒≤pred : ∀ {m n} → m < n → m ≤ pred n
<⇒≤pred (s≤s le) = le
<⇒≤ : _<_ ⇒ _≤_
<⇒≤ (s≤s m≤n) = ≤-trans m≤n (≤-step ≤-refl)
<⇒≢ : _<_ ⇒ _≢_
<⇒≢ m<n refl = 1+n≰n m<n
<⇒≱ : _<_ ⇒ _≱_
<⇒≱ (s≤s m+1≤n) (s≤s n≤m) = <⇒≱ m+1≤n n≤m
<⇒≯ : _<_ ⇒ _≯_
<⇒≯ (s≤s m<n) (s≤s n<m) = <⇒≯ m<n n<m
≰⇒≮ : _≰_ ⇒ _≮_
≰⇒≮ m≰n 1+m≤n = m≰n (<⇒≤ 1+m≤n)
≰⇒> : _≰_ ⇒ _>_
≰⇒> {zero} z≰n = contradiction z≤n z≰n
≰⇒> {suc m} {zero} _ = s≤s z≤n
≰⇒> {suc m} {suc n} m≰n = s≤s (≰⇒> (m≰n ∘ s≤s))
≰⇒≥ : _≰_ ⇒ _≥_
≰⇒≥ = <⇒≤ ∘ ≰⇒>
≮⇒≥ : _≮_ ⇒ _≥_
≮⇒≥ {_} {zero} _ = z≤n
≮⇒≥ {zero} {suc j} 1≮j+1 = contradiction (s≤s z≤n) 1≮j+1
≮⇒≥ {suc i} {suc j} i+1≮j+1 = s≤s (≮⇒≥ (i+1≮j+1 ∘ s≤s))
≤+≢⇒< : ∀ {m n} → m ≤ n → m ≢ n → m < n
≤+≢⇒< {_} {zero} z≤n m≢n = contradiction refl m≢n
≤+≢⇒< {_} {suc n} z≤n m≢n = s≤s z≤n
≤+≢⇒< {_} {suc n} (s≤s m≤n) 1+m≢1+n =
s≤s (≤+≢⇒< m≤n (1+m≢1+n ∘ cong suc))
z≤′n : ∀ {n} → zero ≤′ n
z≤′n {zero} = ≤′-refl
z≤′n {suc n} = ≤′-step z≤′n
s≤′s : ∀ {m n} → m ≤′ n → suc m ≤′ suc n
s≤′s ≤′-refl = ≤′-refl
s≤′s (≤′-step m≤′n) = ≤′-step (s≤′s m≤′n)
≤′⇒≤ : _≤′_ ⇒ _≤_
≤′⇒≤ ≤′-refl = ≤-refl
≤′⇒≤ (≤′-step m≤′n) = ≤-step (≤′⇒≤ m≤′n)
≤⇒≤′ : _≤_ ⇒ _≤′_
≤⇒≤′ z≤n = z≤′n
≤⇒≤′ (s≤s m≤n) = s≤′s (≤⇒≤′ m≤n)
≤″⇒≤ : _≤″_ ⇒ _≤_
≤″⇒≤ {zero} (less-than-or-equal refl) = z≤n
≤″⇒≤ {suc m} (less-than-or-equal refl) =
s≤s (≤″⇒≤ (less-than-or-equal refl))
≤⇒≤″ : _≤_ ⇒ _≤″_
≤⇒≤″ m≤n = less-than-or-equal (proof m≤n)
where
k : ∀ m n → m ≤ n → ℕ
k zero n _ = n
k (suc m) zero ()
k (suc m) (suc n) m≤n = k m n (≤-pred m≤n)
proof : ∀ {m n} (m≤n : m ≤ n) → m + k m n m≤n ≡ n
proof z≤n = refl
proof (s≤s m≤n) = cong suc (proof m≤n)
+-suc : ∀ m n → m + suc n ≡ suc (m + n)
+-suc zero n = refl
+-suc (suc m) n = cong suc (+-suc m n)
+-assoc : Associative _+_
+-assoc zero _ _ = refl
+-assoc (suc m) n o = cong suc (+-assoc m n o)
+-identityˡ : LeftIdentity 0 _+_
+-identityˡ _ = refl
+-identityʳ : RightIdentity 0 _+_
+-identityʳ zero = refl
+-identityʳ (suc n) = cong suc (+-identityʳ n)
+-identity : Identity 0 _+_
+-identity = +-identityˡ , +-identityʳ
+-comm : Commutative _+_
+-comm zero n = sym (+-identityʳ n)
+-comm (suc m) n = begin
suc m + n ≡⟨⟩
suc (m + n) ≡⟨ cong suc (+-comm m n) ⟩
suc (n + m) ≡⟨ sym (+-suc n m) ⟩
n + suc m ∎
+-isSemigroup : IsSemigroup _≡_ _+_
+-isSemigroup = record
{ isEquivalence = isEquivalence
; assoc = +-assoc
; ∙-cong = cong₂ _+_
}
+-semigroup : Semigroup _ _
+-semigroup = record { isSemigroup = +-isSemigroup }
+-0-isCommutativeMonoid : IsCommutativeMonoid _≡_ _+_ 0
+-0-isCommutativeMonoid = record
{ isSemigroup = +-isSemigroup
; identityˡ = +-identityˡ
; comm = +-comm
}
+-0-monoid : Monoid _ _
+-0-monoid = record { isMonoid = IsCommutativeMonoid.isMonoid +-0-isCommutativeMonoid }
+-0-commutativeMonoid : CommutativeMonoid _ _
+-0-commutativeMonoid = record { isCommutativeMonoid = +-0-isCommutativeMonoid }
+-cancelˡ-≡ : LeftCancellative _≡_ _+_
+-cancelˡ-≡ zero eq = eq
+-cancelˡ-≡ (suc m) eq = +-cancelˡ-≡ m (cong pred eq)
+-cancelʳ-≡ : RightCancellative _≡_ _+_
+-cancelʳ-≡ = comm+cancelˡ⇒cancelʳ +-comm +-cancelˡ-≡
+-cancel-≡ : Cancellative _≡_ _+_
+-cancel-≡ = +-cancelˡ-≡ , +-cancelʳ-≡
m≢1+m+n : ∀ m {n} → m ≢ suc (m + n)
m≢1+m+n zero ()
m≢1+m+n (suc m) eq = m≢1+m+n m (cong pred eq)
i+1+j≢i : ∀ i {j} → i + suc j ≢ i
i+1+j≢i zero ()
i+1+j≢i (suc i) = (i+1+j≢i i) ∘ suc-injective
i+j≡0⇒i≡0 : ∀ i {j} → i + j ≡ 0 → i ≡ 0
i+j≡0⇒i≡0 zero eq = refl
i+j≡0⇒i≡0 (suc i) ()
i+j≡0⇒j≡0 : ∀ i {j} → i + j ≡ 0 → j ≡ 0
i+j≡0⇒j≡0 i {j} i+j≡0 = i+j≡0⇒i≡0 j (trans (+-comm j i) (i+j≡0))
+-cancelˡ-≤ : LeftCancellative _≤_ _+_
+-cancelˡ-≤ zero le = le
+-cancelˡ-≤ (suc m) (s≤s le) = +-cancelˡ-≤ m le
+-cancelʳ-≤ : RightCancellative _≤_ _+_
+-cancelʳ-≤ {m} n o le =
+-cancelˡ-≤ m (subst₂ _≤_ (+-comm n m) (+-comm o m) le)
+-cancel-≤ : Cancellative _≤_ _+_
+-cancel-≤ = +-cancelˡ-≤ , +-cancelʳ-≤
m≤m+n : ∀ m n → m ≤ m + n
m≤m+n zero n = z≤n
m≤m+n (suc m) n = s≤s (m≤m+n m n)
n≤m+n : ∀ m n → n ≤ m + n
n≤m+n m zero = z≤n
n≤m+n m (suc n) = subst (suc n ≤_) (sym (+-suc m n)) (s≤s (n≤m+n m n))
≤-steps : ∀ {m n} k → m ≤ n → m ≤ k + n
≤-steps zero m≤n = m≤n
≤-steps (suc k) m≤n = ≤-step (≤-steps k m≤n)
m+n≤o⇒m≤o : ∀ m {n o} → m + n ≤ o → m ≤ o
m+n≤o⇒m≤o zero m+n≤o = z≤n
m+n≤o⇒m≤o (suc m) (s≤s m+n≤o) = s≤s (m+n≤o⇒m≤o m m+n≤o)
m+n≤o⇒n≤o : ∀ m {n o} → m + n ≤ o → n ≤ o
m+n≤o⇒n≤o zero n≤o = n≤o
m+n≤o⇒n≤o (suc m) m+n<o = m+n≤o⇒n≤o m (<⇒≤ m+n<o)
+-mono-≤ : _+_ Preserves₂ _≤_ ⟶ _≤_ ⟶ _≤_
+-mono-≤ {_} {m} z≤n o≤p = ≤-trans o≤p (n≤m+n m _)
+-mono-≤ {_} {_} (s≤s m≤n) o≤p = s≤s (+-mono-≤ m≤n o≤p)
+-monoˡ-< : _+_ Preserves₂ _<_ ⟶ _≤_ ⟶ _<_
+-monoˡ-< {_} {suc y} (s≤s z≤n) u≤v = s≤s (≤-steps y u≤v)
+-monoˡ-< {_} {_} (s≤s (s≤s x<y)) u≤v = s≤s (+-monoˡ-< (s≤s x<y) u≤v)
+-monoʳ-< : _+_ Preserves₂ _≤_ ⟶ _<_ ⟶ _<_
+-monoʳ-< {_} {y} z≤n u<v = ≤-trans u<v (n≤m+n y _)
+-monoʳ-< {_} {_} (s≤s x≤y) u<v = s≤s (+-monoʳ-< x≤y u<v)
+-mono-< : _+_ Preserves₂ _<_ ⟶ _<_ ⟶ _<_
+-mono-< x≤y = +-monoʳ-< (<⇒≤ x≤y)
¬i+1+j≤i : ∀ i {j} → i + suc j ≰ i
¬i+1+j≤i zero ()
¬i+1+j≤i (suc i) le = ¬i+1+j≤i i (≤-pred le)
m+n≮n : ∀ m n → m + n ≮ n
m+n≮n zero n = <-irrefl refl
m+n≮n (suc m) (suc n) (s≤s m+n<n) = m+n≮n m (suc n) (≤-step m+n<n)
m≤′m+n : ∀ m n → m ≤′ m + n
m≤′m+n m n = ≤⇒≤′ (m≤m+n m n)
n≤′m+n : ∀ m n → n ≤′ m + n
n≤′m+n zero n = ≤′-refl
n≤′m+n (suc m) n = ≤′-step (n≤′m+n m n)
+-*-suc : ∀ m n → m * suc n ≡ m + m * n
+-*-suc zero n = refl
+-*-suc (suc m) n = begin
suc m * suc n ≡⟨⟩
suc n + m * suc n ≡⟨ cong (suc n +_) (+-*-suc m n) ⟩
suc n + (m + m * n) ≡⟨⟩
suc (n + (m + m * n)) ≡⟨ cong suc (sym (+-assoc n m (m * n))) ⟩
suc (n + m + m * n) ≡⟨ cong (λ x → suc (x + m * n)) (+-comm n m) ⟩
suc (m + n + m * n) ≡⟨ cong suc (+-assoc m n (m * n)) ⟩
suc (m + (n + m * n)) ≡⟨⟩
suc m + suc m * n ∎
*-identityˡ : LeftIdentity 1 _*_
*-identityˡ x = +-identityʳ x
*-identityʳ : RightIdentity 1 _*_
*-identityʳ zero = refl
*-identityʳ (suc x) = cong suc (*-identityʳ x)
*-identity : Identity 1 _*_
*-identity = *-identityˡ , *-identityʳ
*-zeroˡ : LeftZero 0 _*_
*-zeroˡ _ = refl
*-zeroʳ : RightZero 0 _*_
*-zeroʳ zero = refl
*-zeroʳ (suc n) = *-zeroʳ n
*-zero : Zero 0 _*_
*-zero = *-zeroˡ , *-zeroʳ
*-comm : Commutative _*_
*-comm zero n = sym (*-zeroʳ n)
*-comm (suc m) n = begin
suc m * n ≡⟨⟩
n + m * n ≡⟨ cong (n +_) (*-comm m n) ⟩
n + n * m ≡⟨ sym (+-*-suc n m) ⟩
n * suc m ∎
*-distribʳ-+ : _*_ DistributesOverʳ _+_
*-distribʳ-+ m zero o = refl
*-distribʳ-+ m (suc n) o = begin
(suc n + o) * m ≡⟨⟩
m + (n + o) * m ≡⟨ cong (m +_) (*-distribʳ-+ m n o) ⟩
m + (n * m + o * m) ≡⟨ sym (+-assoc m (n * m) (o * m)) ⟩
m + n * m + o * m ≡⟨⟩
suc n * m + o * m ∎
*-distribˡ-+ : _*_ DistributesOverˡ _+_
*-distribˡ-+ = comm+distrʳ⇒distrˡ (cong₂ _+_) *-comm *-distribʳ-+
*-distrib-+ : _*_ DistributesOver _+_
*-distrib-+ = *-distribˡ-+ , *-distribʳ-+
*-assoc : Associative _*_
*-assoc zero n o = refl
*-assoc (suc m) n o = begin
(suc m * n) * o ≡⟨⟩
(n + m * n) * o ≡⟨ *-distribʳ-+ o n (m * n) ⟩
n * o + (m * n) * o ≡⟨ cong (n * o +_) (*-assoc m n o) ⟩
n * o + m * (n * o) ≡⟨⟩
suc m * (n * o) ∎
*-isSemigroup : IsSemigroup _≡_ _*_
*-isSemigroup = record
{ isEquivalence = isEquivalence
; assoc = *-assoc
; ∙-cong = cong₂ _*_
}
*-semigroup : Semigroup _ _
*-semigroup = record { isSemigroup = *-isSemigroup }
*-1-isCommutativeMonoid : IsCommutativeMonoid _≡_ _*_ 1
*-1-isCommutativeMonoid = record
{ isSemigroup = *-isSemigroup
; identityˡ = *-identityˡ
; comm = *-comm
}
*-1-monoid : Monoid _ _
*-1-monoid = record { isMonoid = IsCommutativeMonoid.isMonoid *-1-isCommutativeMonoid }
*-1-commutativeMonoid : CommutativeMonoid _ _
*-1-commutativeMonoid = record { isCommutativeMonoid = *-1-isCommutativeMonoid }
*-+-isCommutativeSemiring : IsCommutativeSemiring _≡_ _+_ _*_ 0 1
*-+-isCommutativeSemiring = record
{ +-isCommutativeMonoid = +-0-isCommutativeMonoid
; *-isCommutativeMonoid = *-1-isCommutativeMonoid
; distribʳ = *-distribʳ-+
; zeroˡ = *-zeroˡ
}
*-+-semiring : Semiring _ _
*-+-semiring = record { isSemiring = IsCommutativeSemiring.isSemiring *-+-isCommutativeSemiring }
*-+-commutativeSemiring : CommutativeSemiring _ _
*-+-commutativeSemiring = record
{ isCommutativeSemiring = *-+-isCommutativeSemiring
}
*-cancelʳ-≡ : ∀ i j {k} → i * suc k ≡ j * suc k → i ≡ j
*-cancelʳ-≡ zero zero eq = refl
*-cancelʳ-≡ zero (suc j) ()
*-cancelʳ-≡ (suc i) zero ()
*-cancelʳ-≡ (suc i) (suc j) {k} eq =
cong suc (*-cancelʳ-≡ i j (+-cancelˡ-≡ (suc k) eq))
*-cancelˡ-≡ : ∀ {i j} k → suc k * i ≡ suc k * j → i ≡ j
*-cancelˡ-≡ {i} {j} k eq = *-cancelʳ-≡ i j
(subst₂ _≡_ (*-comm (suc k) i) (*-comm (suc k) j) eq)
i*j≡0⇒i≡0∨j≡0 : ∀ i {j} → i * j ≡ 0 → i ≡ 0 ⊎ j ≡ 0
i*j≡0⇒i≡0∨j≡0 zero {j} eq = inj₁ refl
i*j≡0⇒i≡0∨j≡0 (suc i) {zero} eq = inj₂ refl
i*j≡0⇒i≡0∨j≡0 (suc i) {suc j} ()
i*j≡1⇒i≡1 : ∀ i j → i * j ≡ 1 → i ≡ 1
i*j≡1⇒i≡1 (suc zero) j _ = refl
i*j≡1⇒i≡1 zero j ()
i*j≡1⇒i≡1 (suc (suc i)) (suc (suc j)) ()
i*j≡1⇒i≡1 (suc (suc i)) (suc zero) ()
i*j≡1⇒i≡1 (suc (suc i)) zero eq =
contradiction (trans (*-comm 0 i) eq) λ()
i*j≡1⇒j≡1 : ∀ i j → i * j ≡ 1 → j ≡ 1
i*j≡1⇒j≡1 i j eq = i*j≡1⇒i≡1 j i (trans (*-comm j i) eq)
*-cancelʳ-≤ : ∀ i j k → i * suc k ≤ j * suc k → i ≤ j
*-cancelʳ-≤ zero _ _ _ = z≤n
*-cancelʳ-≤ (suc i) zero _ ()
*-cancelʳ-≤ (suc i) (suc j) k le =
s≤s (*-cancelʳ-≤ i j k (+-cancelˡ-≤ (suc k) le))
*-mono-≤ : _*_ Preserves₂ _≤_ ⟶ _≤_ ⟶ _≤_
*-mono-≤ z≤n _ = z≤n
*-mono-≤ (s≤s m≤n) u≤v = +-mono-≤ u≤v (*-mono-≤ m≤n u≤v)
*-mono-< : _*_ Preserves₂ _<_ ⟶ _<_ ⟶ _<_
*-mono-< (s≤s z≤n) (s≤s u≤v) = s≤s z≤n
*-mono-< (s≤s (s≤s m≤n)) (s≤s u≤v) =
+-mono-< (s≤s u≤v) (*-mono-< (s≤s m≤n) (s≤s u≤v))
*-monoˡ-< : ∀ n → (_* suc n) Preserves _<_ ⟶ _<_
*-monoˡ-< n (s≤s z≤n) = s≤s z≤n
*-monoˡ-< n (s≤s (s≤s m≤o)) =
+-monoʳ-< (≤-refl {suc n}) (*-monoˡ-< n (s≤s m≤o))
*-monoʳ-< : ∀ n → (suc n *_) Preserves _<_ ⟶ _<_
*-monoʳ-< zero (s≤s m≤o) = +-mono-≤ (s≤s m≤o) z≤n
*-monoʳ-< (suc n) (s≤s m≤o) =
+-mono-≤ (s≤s m≤o) (<⇒≤ (*-monoʳ-< n (s≤s m≤o)))
^-distribˡ-+-* : ∀ m n p → m ^ (n + p) ≡ m ^ n * m ^ p
^-distribˡ-+-* m zero p = sym (+-identityʳ (m ^ p))
^-distribˡ-+-* m (suc n) p = begin
m * (m ^ (n + p)) ≡⟨ cong (m *_) (^-distribˡ-+-* m n p) ⟩
m * ((m ^ n) * (m ^ p)) ≡⟨ sym (*-assoc m _ _) ⟩
(m * (m ^ n)) * (m ^ p) ∎
i^j≡0⇒i≡0 : ∀ i j → i ^ j ≡ 0 → i ≡ 0
i^j≡0⇒i≡0 i zero ()
i^j≡0⇒i≡0 i (suc j) eq = [ id , i^j≡0⇒i≡0 i j ]′ (i*j≡0⇒i≡0∨j≡0 i eq)
i^j≡1⇒j≡0∨i≡1 : ∀ i j → i ^ j ≡ 1 → j ≡ 0 ⊎ i ≡ 1
i^j≡1⇒j≡0∨i≡1 i zero _ = inj₁ refl
i^j≡1⇒j≡0∨i≡1 i (suc j) eq = inj₂ (i*j≡1⇒i≡1 i (i ^ j) eq)
^-semigroup-morphism : ∀ {n} → (n ^_) Is +-semigroup -Semigroup⟶ *-semigroup
^-semigroup-morphism = record
{ ⟦⟧-cong = cong (_ ^_)
; ∙-homo = ^-distribˡ-+-* _
}
^-monoid-morphism : ∀ {n} → (n ^_) Is +-0-monoid -Monoid⟶ *-1-monoid
^-monoid-morphism = record
{ sm-homo = ^-semigroup-morphism
; ε-homo = refl
}
⊔-assoc : Associative _⊔_
⊔-assoc zero _ _ = refl
⊔-assoc (suc m) zero o = refl
⊔-assoc (suc m) (suc n) zero = refl
⊔-assoc (suc m) (suc n) (suc o) = cong suc $ ⊔-assoc m n o
⊔-identityˡ : LeftIdentity 0 _⊔_
⊔-identityˡ _ = refl
⊔-identityʳ : RightIdentity 0 _⊔_
⊔-identityʳ zero = refl
⊔-identityʳ (suc n) = refl
⊔-identity : Identity 0 _⊔_
⊔-identity = ⊔-identityˡ , ⊔-identityʳ
⊔-comm : Commutative _⊔_
⊔-comm zero n = sym $ ⊔-identityʳ n
⊔-comm (suc m) zero = refl
⊔-comm (suc m) (suc n) = cong suc (⊔-comm m n)
⊔-sel : Selective _⊔_
⊔-sel zero _ = inj₂ refl
⊔-sel (suc m) zero = inj₁ refl
⊔-sel (suc m) (suc n) with ⊔-sel m n
... | inj₁ m⊔n≡m = inj₁ (cong suc m⊔n≡m)
... | inj₂ m⊔n≡n = inj₂ (cong suc m⊔n≡n)
⊔-idem : Idempotent _⊔_
⊔-idem = sel⇒idem ⊔-sel
⊓-assoc : Associative _⊓_
⊓-assoc zero _ _ = refl
⊓-assoc (suc m) zero o = refl
⊓-assoc (suc m) (suc n) zero = refl
⊓-assoc (suc m) (suc n) (suc o) = cong suc $ ⊓-assoc m n o
⊓-zeroˡ : LeftZero 0 _⊓_
⊓-zeroˡ _ = refl
⊓-zeroʳ : RightZero 0 _⊓_
⊓-zeroʳ zero = refl
⊓-zeroʳ (suc n) = refl
⊓-zero : Zero 0 _⊓_
⊓-zero = ⊓-zeroˡ , ⊓-zeroʳ
⊓-comm : Commutative _⊓_
⊓-comm zero n = sym $ ⊓-zeroʳ n
⊓-comm (suc m) zero = refl
⊓-comm (suc m) (suc n) = cong suc (⊓-comm m n)
⊓-sel : Selective _⊓_
⊓-sel zero _ = inj₁ refl
⊓-sel (suc m) zero = inj₂ refl
⊓-sel (suc m) (suc n) with ⊓-sel m n
... | inj₁ m⊓n≡m = inj₁ (cong suc m⊓n≡m)
... | inj₂ m⊓n≡n = inj₂ (cong suc m⊓n≡n)
⊓-idem : Idempotent _⊓_
⊓-idem = sel⇒idem ⊓-sel
⊓-distribʳ-⊔ : _⊓_ DistributesOverʳ _⊔_
⊓-distribʳ-⊔ (suc m) (suc n) (suc o) = cong suc $ ⊓-distribʳ-⊔ m n o
⊓-distribʳ-⊔ (suc m) (suc n) zero = cong suc $ refl
⊓-distribʳ-⊔ (suc m) zero o = refl
⊓-distribʳ-⊔ zero n o = begin
(n ⊔ o) ⊓ 0 ≡⟨ ⊓-comm (n ⊔ o) 0 ⟩
0 ⊓ (n ⊔ o) ≡⟨⟩
0 ⊓ n ⊔ 0 ⊓ o ≡⟨ ⊓-comm 0 n ⟨ cong₂ _⊔_ ⟩ ⊓-comm 0 o ⟩
n ⊓ 0 ⊔ o ⊓ 0 ∎
⊓-distribˡ-⊔ : _⊓_ DistributesOverˡ _⊔_
⊓-distribˡ-⊔ = comm+distrʳ⇒distrˡ (cong₂ _⊔_) ⊓-comm ⊓-distribʳ-⊔
⊓-distrib-⊔ : _⊓_ DistributesOver _⊔_
⊓-distrib-⊔ = ⊓-distribˡ-⊔ , ⊓-distribʳ-⊔
⊔-abs-⊓ : _⊔_ Absorbs _⊓_
⊔-abs-⊓ zero n = refl
⊔-abs-⊓ (suc m) zero = refl
⊔-abs-⊓ (suc m) (suc n) = cong suc $ ⊔-abs-⊓ m n
⊓-abs-⊔ : _⊓_ Absorbs _⊔_
⊓-abs-⊔ zero n = refl
⊓-abs-⊔ (suc m) (suc n) = cong suc $ ⊓-abs-⊔ m n
⊓-abs-⊔ (suc m) zero = cong suc $ begin
m ⊓ m ≡⟨ cong (m ⊓_) $ sym $ ⊔-identityʳ m ⟩
m ⊓ (m ⊔ 0) ≡⟨ ⊓-abs-⊔ m zero ⟩
m ∎
⊓-⊔-absorptive : Absorptive _⊓_ _⊔_
⊓-⊔-absorptive = ⊓-abs-⊔ , ⊔-abs-⊓
⊔-isSemigroup : IsSemigroup _≡_ _⊔_
⊔-isSemigroup = record
{ isEquivalence = isEquivalence
; assoc = ⊔-assoc
; ∙-cong = cong₂ _⊔_
}
⊔-0-isCommutativeMonoid : IsCommutativeMonoid _≡_ _⊔_ 0
⊔-0-isCommutativeMonoid = record
{ isSemigroup = ⊔-isSemigroup
; identityˡ = ⊔-identityˡ
; comm = ⊔-comm
}
⊓-isSemigroup : IsSemigroup _≡_ _⊓_
⊓-isSemigroup = record
{ isEquivalence = isEquivalence
; assoc = ⊓-assoc
; ∙-cong = cong₂ _⊓_
}
⊔-⊓-isSemiringWithoutOne : IsSemiringWithoutOne _≡_ _⊔_ _⊓_ 0
⊔-⊓-isSemiringWithoutOne = record
{ +-isCommutativeMonoid = ⊔-0-isCommutativeMonoid
; *-isSemigroup = ⊓-isSemigroup
; distrib = ⊓-distrib-⊔
; zero = ⊓-zero
}
⊔-⊓-isCommutativeSemiringWithoutOne
: IsCommutativeSemiringWithoutOne _≡_ _⊔_ _⊓_ 0
⊔-⊓-isCommutativeSemiringWithoutOne = record
{ isSemiringWithoutOne = ⊔-⊓-isSemiringWithoutOne
; *-comm = ⊓-comm
}
⊔-⊓-commutativeSemiringWithoutOne : CommutativeSemiringWithoutOne _ _
⊔-⊓-commutativeSemiringWithoutOne = record
{ isCommutativeSemiringWithoutOne =
⊔-⊓-isCommutativeSemiringWithoutOne
}
⊓-⊔-isLattice : IsLattice _≡_ _⊓_ _⊔_
⊓-⊔-isLattice = record
{ isEquivalence = isEquivalence
; ∨-comm = ⊓-comm
; ∨-assoc = ⊓-assoc
; ∨-cong = cong₂ _⊓_
; ∧-comm = ⊔-comm
; ∧-assoc = ⊔-assoc
; ∧-cong = cong₂ _⊔_
; absorptive = ⊓-⊔-absorptive
}
⊓-⊔-isDistributiveLattice : IsDistributiveLattice _≡_ _⊓_ _⊔_
⊓-⊔-isDistributiveLattice = record
{ isLattice = ⊓-⊔-isLattice
; ∨-∧-distribʳ = ⊓-distribʳ-⊔
}
⊓-⊔-distributiveLattice : DistributiveLattice _ _
⊓-⊔-distributiveLattice = record
{ isDistributiveLattice = ⊓-⊔-isDistributiveLattice
}
m⊓n≤m : ∀ m n → m ⊓ n ≤ m
m⊓n≤m zero _ = z≤n
m⊓n≤m (suc m) zero = z≤n
m⊓n≤m (suc m) (suc n) = s≤s $ m⊓n≤m m n
m⊓n≤n : ∀ m n → m ⊓ n ≤ n
m⊓n≤n m n = subst (_≤ n) (⊓-comm n m) (m⊓n≤m n m)
m≤m⊔n : ∀ m n → m ≤ m ⊔ n
m≤m⊔n zero _ = z≤n
m≤m⊔n (suc m) zero = ≤-refl
m≤m⊔n (suc m) (suc n) = s≤s $ m≤m⊔n m n
n≤m⊔n : ∀ m n → n ≤ m ⊔ n
n≤m⊔n m n = subst (n ≤_) (⊔-comm n m) (m≤m⊔n n m)
m⊓n≤m⊔n : ∀ m n → m ⊔ n ≤ m ⊔ n
m⊓n≤m⊔n zero n = ≤-refl
m⊓n≤m⊔n (suc m) zero = ≤-refl
m⊓n≤m⊔n (suc m) (suc n) = s≤s (m⊓n≤m⊔n m n)
⊔-mono-≤ : _⊔_ Preserves₂ _≤_ ⟶ _≤_ ⟶ _≤_
⊔-mono-≤ {x} {y} {u} {v} x≤y u≤v with ⊔-sel x u
... | inj₁ x⊔u≡x rewrite x⊔u≡x = ≤-trans x≤y (m≤m⊔n y v)
... | inj₂ x⊔u≡u rewrite x⊔u≡u = ≤-trans u≤v (n≤m⊔n y v)
⊔-mono-< : _⊔_ Preserves₂ _<_ ⟶ _<_ ⟶ _<_
⊔-mono-< = ⊔-mono-≤
⊓-mono-≤ : _⊓_ Preserves₂ _≤_ ⟶ _≤_ ⟶ _≤_
⊓-mono-≤ {x} {y} {u} {v} x≤y u≤v with ⊓-sel y v
... | inj₁ y⊓v≡y rewrite y⊓v≡y = ≤-trans (m⊓n≤m x u) x≤y
... | inj₂ y⊓v≡v rewrite y⊓v≡v = ≤-trans (m⊓n≤n x u) u≤v
⊓-mono-< : _⊓_ Preserves₂ _<_ ⟶ _<_ ⟶ _<_
⊓-mono-< = ⊓-mono-≤
m⊔n≤m+n : ∀ m n → m ⊔ n ≤ m + n
m⊔n≤m+n m n with ⊔-sel m n
... | inj₁ m⊔n≡m rewrite m⊔n≡m = m≤m+n m n
... | inj₂ m⊔n≡n rewrite m⊔n≡n = n≤m+n m n
m⊓n≤m+n : ∀ m n → m ⊓ n ≤ m + n
m⊓n≤m+n m n with ⊓-sel m n
... | inj₁ m⊓n≡m rewrite m⊓n≡m = m≤m+n m n
... | inj₂ m⊓n≡n rewrite m⊓n≡n = n≤m+n m n
+-distribˡ-⊔ : _+_ DistributesOverˡ _⊔_
+-distribˡ-⊔ zero y z = refl
+-distribˡ-⊔ (suc x) y z = cong suc (+-distribˡ-⊔ x y z)
+-distribʳ-⊔ : _+_ DistributesOverʳ _⊔_
+-distribʳ-⊔ = comm+distrˡ⇒distrʳ (cong₂ _⊔_) +-comm +-distribˡ-⊔
+-distrib-⊔ : _+_ DistributesOver _⊔_
+-distrib-⊔ = +-distribˡ-⊔ , +-distribʳ-⊔
+-distribˡ-⊓ : _+_ DistributesOverˡ _⊓_
+-distribˡ-⊓ zero y z = refl
+-distribˡ-⊓ (suc x) y z = cong suc (+-distribˡ-⊓ x y z)
+-distribʳ-⊓ : _+_ DistributesOverʳ _⊓_
+-distribʳ-⊓ = comm+distrˡ⇒distrʳ (cong₂ _⊓_) +-comm +-distribˡ-⊓
+-distrib-⊓ : _+_ DistributesOver _⊓_
+-distrib-⊓ = +-distribˡ-⊓ , +-distribʳ-⊓
0∸n≡0 : LeftZero zero _∸_
0∸n≡0 zero = refl
0∸n≡0 (suc _) = refl
n∸n≡0 : ∀ n → n ∸ n ≡ 0
n∸n≡0 zero = refl
n∸n≡0 (suc n) = n∸n≡0 n
+-∸-comm : ∀ {m} n {o} → o ≤ m → (m + n) ∸ o ≡ (m ∸ o) + n
+-∸-comm {zero} _ {suc o} ()
+-∸-comm {zero} _ {zero} _ = refl
+-∸-comm {suc m} _ {zero} _ = refl
+-∸-comm {suc m} n {suc o} (s≤s o≤m) = +-∸-comm n o≤m
∸-+-assoc : ∀ m n o → (m ∸ n) ∸ o ≡ m ∸ (n + o)
∸-+-assoc m n zero = cong (m ∸_) (sym $ +-identityʳ n)
∸-+-assoc zero zero (suc o) = refl
∸-+-assoc zero (suc n) (suc o) = refl
∸-+-assoc (suc m) zero (suc o) = refl
∸-+-assoc (suc m) (suc n) (suc o) = ∸-+-assoc m n (suc o)
+-∸-assoc : ∀ m {n o} → o ≤ n → (m + n) ∸ o ≡ m + (n ∸ o)
+-∸-assoc m (z≤n {n = n}) = begin m + n ∎
+-∸-assoc m (s≤s {m = o} {n = n} o≤n) = begin
(m + suc n) ∸ suc o ≡⟨ cong (_∸ suc o) (+-suc m n) ⟩
suc (m + n) ∸ suc o ≡⟨⟩
(m + n) ∸ o ≡⟨ +-∸-assoc m o≤n ⟩
m + (n ∸ o) ∎
n∸m≤n : ∀ m n → n ∸ m ≤ n
n∸m≤n zero n = ≤-refl
n∸m≤n (suc m) zero = ≤-refl
n∸m≤n (suc m) (suc n) = ≤-trans (n∸m≤n m n) (n≤1+n n)
n≤m+n∸m : ∀ m n → n ≤ m + (n ∸ m)
n≤m+n∸m m zero = z≤n
n≤m+n∸m zero (suc n) = ≤-refl
n≤m+n∸m (suc m) (suc n) = s≤s (n≤m+n∸m m n)
m+n∸n≡m : ∀ m n → (m + n) ∸ n ≡ m
m+n∸n≡m m n = begin
(m + n) ∸ n ≡⟨ +-∸-assoc m (≤-refl {x = n}) ⟩
m + (n ∸ n) ≡⟨ cong (m +_) (n∸n≡0 n) ⟩
m + 0 ≡⟨ +-identityʳ m ⟩
m ∎
m+n∸m≡n : ∀ {m n} → m ≤ n → m + (n ∸ m) ≡ n
m+n∸m≡n {m} {n} m≤n = begin
m + (n ∸ m) ≡⟨ sym $ +-∸-assoc m m≤n ⟩
(m + n) ∸ m ≡⟨ cong (_∸ m) (+-comm m n) ⟩
(n + m) ∸ m ≡⟨ m+n∸n≡m n m ⟩
n ∎
m∸n+n≡m : ∀ {m n} → n ≤ m → (m ∸ n) + n ≡ m
m∸n+n≡m {m} {n} n≤m = trans (sym (+-∸-comm n n≤m)) (m+n∸n≡m m n)
m⊓n+n∸m≡n : ∀ m n → (m ⊓ n) + (n ∸ m) ≡ n
m⊓n+n∸m≡n zero n = refl
m⊓n+n∸m≡n (suc m) zero = refl
m⊓n+n∸m≡n (suc m) (suc n) = cong suc $ m⊓n+n∸m≡n m n
[m∸n]⊓[n∸m]≡0 : ∀ m n → (m ∸ n) ⊓ (n ∸ m) ≡ 0
[m∸n]⊓[n∸m]≡0 zero zero = refl
[m∸n]⊓[n∸m]≡0 zero (suc n) = refl
[m∸n]⊓[n∸m]≡0 (suc m) zero = refl
[m∸n]⊓[n∸m]≡0 (suc m) (suc n) = [m∸n]⊓[n∸m]≡0 m n
[i+j]∸[i+k]≡j∸k : ∀ i j k → (i + j) ∸ (i + k) ≡ j ∸ k
[i+j]∸[i+k]≡j∸k zero j k = refl
[i+j]∸[i+k]≡j∸k (suc i) j k = [i+j]∸[i+k]≡j∸k i j k
*-distribʳ-∸ : _*_ DistributesOverʳ _∸_
*-distribʳ-∸ i zero k = begin
(0 ∸ k) * i ≡⟨ cong (_* i) (0∸n≡0 k) ⟩
0 ≡⟨ sym $ 0∸n≡0 (k * i) ⟩
0 ∸ (k * i) ∎
*-distribʳ-∸ i (suc j) zero = refl
*-distribʳ-∸ i (suc j) (suc k) = begin
(j ∸ k) * i ≡⟨ *-distribʳ-∸ i j k ⟩
j * i ∸ k * i ≡⟨ sym $ [i+j]∸[i+k]≡j∸k i _ _ ⟩
i + j * i ∸ (i + k * i) ∎
∸-distribʳ-⊓ : _∸_ DistributesOverʳ _⊓_
∸-distribʳ-⊓ zero y z = refl
∸-distribʳ-⊓ (suc x) zero z = refl
∸-distribʳ-⊓ (suc x) (suc y) zero = sym (⊓-zeroʳ (y ∸ x))
∸-distribʳ-⊓ (suc x) (suc y) (suc z) = ∸-distribʳ-⊓ x y z
∸-distribʳ-⊔ : _∸_ DistributesOverʳ _⊔_
∸-distribʳ-⊔ zero y z = refl
∸-distribʳ-⊔ (suc x) zero z = refl
∸-distribʳ-⊔ (suc x) (suc y) zero = sym (⊔-identityʳ (y ∸ x))
∸-distribʳ-⊔ (suc x) (suc y) (suc z) = ∸-distribʳ-⊔ x y z
∸-mono : _∸_ Preserves₂ _≤_ ⟶ _≥_ ⟶ _≤_
∸-mono z≤n (s≤s n₁≥n₂) = z≤n
∸-mono (s≤s m₁≤m₂) (s≤s n₁≥n₂) = ∸-mono m₁≤m₂ n₁≥n₂
∸-mono m₁≤m₂ (z≤n {n = n₁}) = ≤-trans (n∸m≤n n₁ _) m₁≤m₂
i∸k∸j+j∸k≡i+j∸k : ∀ i j k → i ∸ (k ∸ j) + (j ∸ k) ≡ i + j ∸ k
i∸k∸j+j∸k≡i+j∸k zero j k = cong (_+ (j ∸ k)) (0∸n≡0 (k ∸ j))
i∸k∸j+j∸k≡i+j∸k (suc i) j zero = cong (λ x → suc i ∸ x + j) (0∸n≡0 j)
i∸k∸j+j∸k≡i+j∸k (suc i) zero (suc k) = begin
i ∸ k + 0 ≡⟨ +-identityʳ _ ⟩
i ∸ k ≡⟨ cong (_∸ k) (sym (+-identityʳ _)) ⟩
i + 0 ∸ k ∎
i∸k∸j+j∸k≡i+j∸k (suc i) (suc j) (suc k) = begin
suc i ∸ (k ∸ j) + (j ∸ k) ≡⟨ i∸k∸j+j∸k≡i+j∸k (suc i) j k ⟩
suc i + j ∸ k ≡⟨ cong (_∸ k) (sym (+-suc i j)) ⟩
i + suc j ∸ k ∎
im≡jm+n⇒[i∸j]m≡n : ∀ i j m n → i * m ≡ j * m + n → (i ∸ j) * m ≡ n
im≡jm+n⇒[i∸j]m≡n i j m n eq = begin
(i ∸ j) * m ≡⟨ *-distribʳ-∸ m i j ⟩
(i * m) ∸ (j * m) ≡⟨ cong (_∸ j * m) eq ⟩
(j * m + n) ∸ (j * m) ≡⟨ cong (_∸ j * m) (+-comm (j * m) n) ⟩
(n + j * m) ∸ (j * m) ≡⟨ m+n∸n≡m n (j * m) ⟩
n ∎
⌊n/2⌋-mono : ⌊_/2⌋ Preserves _≤_ ⟶ _≤_
⌊n/2⌋-mono z≤n = z≤n
⌊n/2⌋-mono (s≤s z≤n) = z≤n
⌊n/2⌋-mono (s≤s (s≤s m≤n)) = s≤s (⌊n/2⌋-mono m≤n)
⌈n/2⌉-mono : ⌈_/2⌉ Preserves _≤_ ⟶ _≤_
⌈n/2⌉-mono m≤n = ⌊n/2⌋-mono (s≤s m≤n)
⌈n/2⌉≤′n : ∀ n → ⌈ n /2⌉ ≤′ n
⌈n/2⌉≤′n zero = ≤′-refl
⌈n/2⌉≤′n (suc zero) = ≤′-refl
⌈n/2⌉≤′n (suc (suc n)) = s≤′s (≤′-step (⌈n/2⌉≤′n n))
⌊n/2⌋≤′n : ∀ n → ⌊ n /2⌋ ≤′ n
⌊n/2⌋≤′n zero = ≤′-refl
⌊n/2⌋≤′n (suc n) = ≤′-step (⌈n/2⌉≤′n n)
module SemiringSolver =
Solver (ACR.fromCommutativeSemiring *-+-commutativeSemiring) _≟_
module ≤-Reasoning where
open import Relation.Binary.PartialOrderReasoning
(DecTotalOrder.poset ≤-decTotalOrder) public
renaming (_≈⟨_⟩_ to _≡⟨_⟩_)
infixr 2 _<⟨_⟩_
_<⟨_⟩_ : ∀ x {y z} → x < y → y IsRelatedTo z → suc x IsRelatedTo z
x <⟨ x<y ⟩ y≤z = suc x ≤⟨ x<y ⟩ y≤z
_*-mono_ = *-mono-≤
_+-mono_ = +-mono-≤
+-right-identity = +-identityʳ
*-right-zero = *-zeroʳ
distribʳ-*-+ = *-distribʳ-+
*-distrib-∸ʳ = *-distribʳ-∸
cancel-+-left = +-cancelˡ-≡
cancel-+-left-≤ = +-cancelˡ-≤
cancel-*-right = *-cancelʳ-≡
cancel-*-right-≤ = *-cancelʳ-≤
strictTotalOrder = <-strictTotalOrder
isCommutativeSemiring = *-+-isCommutativeSemiring
commutativeSemiring = *-+-commutativeSemiring
isDistributiveLattice = ⊓-⊔-isDistributiveLattice
distributiveLattice = ⊓-⊔-distributiveLattice
⊔-⊓-0-isSemiringWithoutOne = ⊔-⊓-isSemiringWithoutOne
⊔-⊓-0-isCommutativeSemiringWithoutOne = ⊔-⊓-isCommutativeSemiringWithoutOne
⊔-⊓-0-commutativeSemiringWithoutOne = ⊔-⊓-commutativeSemiringWithoutOne