Mercurial > hg > Members > kono > Proof > automaton
view agda/logic.agda @ 76:7b357b295272
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author | Shinji KONO <kono@ie.u-ryukyu.ac.jp> |
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date | Fri, 08 Nov 2019 13:40:25 +0900 |
parents | 762d5a6fbe09 |
children | ed6a39c20098 |
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module logic where open import Level open import Relation.Nullary open import Relation.Binary open import Data.Empty data Bool : Set where true : Bool false : Bool record _∧_ {n m : Level} (A : Set n) ( B : Set m ) : Set (n ⊔ m) where field proj1 : A proj2 : B data _∨_ {n m : Level} (A : Set n) ( B : Set m ) : Set (n ⊔ m) where case1 : A → A ∨ B case2 : B → A ∨ B _⇔_ : {n m : Level } → ( A : Set n ) ( B : Set m ) → Set (n ⊔ m) _⇔_ A B = ( A → B ) ∧ ( B → A ) contra-position : {n m : Level } {A : Set n} {B : Set m} → (A → B) → ¬ B → ¬ A contra-position {n} {m} {A} {B} f ¬b a = ¬b ( f a ) double-neg : {n : Level } {A : Set n} → A → ¬ ¬ A double-neg A notnot = notnot A double-neg2 : {n : Level } {A : Set n} → ¬ ¬ ¬ A → ¬ A double-neg2 notnot A = notnot ( double-neg A ) de-morgan : {n : Level } {A B : Set n} → A ∧ B → ¬ ( (¬ A ) ∨ (¬ B ) ) de-morgan {n} {A} {B} and (case1 ¬A) = ⊥-elim ( ¬A ( _∧_.proj1 and )) de-morgan {n} {A} {B} and (case2 ¬B) = ⊥-elim ( ¬B ( _∧_.proj2 and )) dont-or : {n m : Level} {A : Set n} { B : Set m } → A ∨ B → ¬ A → B dont-or {A} {B} (case1 a) ¬A = ⊥-elim ( ¬A a ) dont-or {A} {B} (case2 b) ¬A = b dont-orb : {n m : Level} {A : Set n} { B : Set m } → A ∨ B → ¬ B → A dont-orb {A} {B} (case2 b) ¬B = ⊥-elim ( ¬B b ) dont-orb {A} {B} (case1 a) ¬B = a infixr 130 _∧_ infixr 140 _∨_ infixr 150 _⇔_ _/\_ : Bool → Bool → Bool true /\ true = true _ /\ _ = false _\/_ : Bool → Bool → Bool false \/ false = false _ \/ _ = true not_ : Bool → Bool not true = false not false = true _<=>_ : Bool → Bool → Bool true <=> true = true false <=> false = true _ <=> _ = false infixr 130 _\/_ infixr 140 _/\_ open import Relation.Binary.PropositionalEquality ≡-Bool-func : {A B : Bool } → ( A ≡ true → B ≡ true ) → ( B ≡ true → A ≡ true ) → A ≡ B ≡-Bool-func {true} {true} a→b b→a = refl ≡-Bool-func {false} {true} a→b b→a with b→a refl ... | () ≡-Bool-func {true} {false} a→b b→a with a→b refl ... | () ≡-Bool-func {false} {false} a→b b→a = refl bool-≡-? : (a b : Bool) → Dec ( a ≡ b ) bool-≡-? true true = yes refl bool-≡-? true false = no (λ ()) bool-≡-? false true = no (λ ()) bool-≡-? false false = yes refl ¬-bool-t : {a : Bool} → ¬ ( a ≡ true ) → a ≡ false ¬-bool-t {true} ne = ⊥-elim ( ne refl ) ¬-bool-t {false} ne = refl ¬-bool-f : {a : Bool} → ¬ ( a ≡ false ) → a ≡ true ¬-bool-f {true} ne = refl ¬-bool-f {false} ne = ⊥-elim ( ne refl ) ¬-bool : {a : Bool} → a ≡ false → a ≡ true → ⊥ ¬-bool refl () lemma-∧-0 : {a b : Bool} → a /\ b ≡ true → a ≡ false → ⊥ lemma-∧-0 {true} {true} refl () lemma-∧-0 {true} {false} () lemma-∧-0 {false} {true} () lemma-∧-0 {false} {false} () lemma-∧-1 : {a b : Bool} → a /\ b ≡ true → b ≡ false → ⊥ lemma-∧-1 {true} {true} refl () lemma-∧-1 {true} {false} () lemma-∧-1 {false} {true} () lemma-∧-1 {false} {false} () bool-or-1 : {a b : Bool} → a ≡ false → ( a \/ b ) ≡ b bool-or-1 {false} {true} refl = refl bool-or-1 {false} {false} refl = refl bool-or-2 : {a b : Bool} → b ≡ false → (a \/ b ) ≡ a bool-or-2 {true} {false} refl = refl bool-or-2 {false} {false} refl = refl bool-or-3 : {a : Bool} → ( a \/ true ) ≡ true bool-or-3 {true} = refl bool-or-3 {false} = refl bool-and-1 : {a b : Bool} → a ≡ false → (a /\ b ) ≡ false bool-and-1 {false} {b} refl = refl bool-and-2 : {a b : Bool} → b ≡ false → (a /\ b ) ≡ false bool-and-2 {true} {false} refl = refl bool-and-2 {false} {false} refl = refl