natural-prime

Entry	Value
Name	natural-prime_30
Conclusion	!n p. MEM p (primes_below n) <=> prime p /\ p < n
Constructive Proof	No
Axiom	!t. t \/ ~t (\a. a = (\b. (\c. c) = (\c. c))) (\d. (\e. d e) = d) (\a. a = (\b. (\c. c) = (\c. c))) (\d. (\e. e = (\f. (\c. c) = (\c. c))) (\g. (\h i. (\j k. (\l. l j k) = (\m. m ((\c. c) = (\c. c)) ((\c. c) = (\c. c)))) h i <=> h) (d g) (d ((@) d)))) (\a. (\b. b = (\c. (\d. d) = (\d. d))) (\e. (\f g. (\h i. (\j. j h i) = (\k. k ((\d. d) = (\d. d)) ((\d. d) = (\d. d)))) f g <=> f) ((\l. l = (\m. (\d. d) = (\d. d))) (\n. (\f g. (\h i. (\j. j h i) = (\k. k ((\d. d) = (\d. d)) ((\d. d) = (\d. d)))) f g <=> f) (a n) e)) e)) (\p. (\h i. (\j. j h i) = (\k. k ((\d. d) = (\d. d)) ((\d. d) = (\d. d)))) ((\q. q = (\r. (\d. d) = (\d. d))) (\s. (\q. q = (\r. (\d. d) = (\d. d))) (\t. (\f g. (\h i. (\j. j h i) = (\k. k ((\d. d) = (\d. d)) ((\d. d) = (\d. d)))) f g <=> f) (p s = p t) (s = t)))) ((\u. (\f g. (\h i. (\j. j h i) = (\k. k ((\d. d) = (\d. d)) ((\d. d) = (\d. d)))) f g <=> f) u ((\b. b = (\c. (\d. d) = (\d. d))) (\d. d))) ((\q. q = (\r. (\d. d) = (\d. d))) (\v. (\w. (\b. b = (\c. (\d. d) = (\d. d))) (\x. (\f g. (\h i. (\j. j h i) = (\k. k ((\d. d) = (\d. d)) ((\d. d) = (\d. d)))) f g <=> f) ((\q. q = (\r. (\d. d) = (\d. d))) (\y. (\f g. (\h i. (\j. j h i) = (\k. k ((\d. d) = (\d. d)) ((\d. d) = (\d. d)))) f g <=> f) (w y) x)) x)) (\z. v = p z)))))
Classical Lemmas	!e f. ?!fn. fn _0 = e /\ (!n. fn (SUC n) = f (fn n) n) !t1 t2. ~(t1 /\ t2) <=> ~t1 \/ ~t2 !t1 t2. ~(t1 ==> t2) <=> t1 /\ ~t2 !t1 t2. ~(t1 \/ t2) <=> ~t1 /\ ~t2 !t. ~ ~t <=> t !t. (t <=> T) \/ (t <=> F) !p c x y. p (if c then x else y) <=> (c ==> p x) /\ (~c ==> p y) !p. (?x. ~p x) <=> ~(!x. p x) !p. ~(!x. p x) <=> (?x. ~p x) !p. ~(?x. p x) <=> (!x. ~p x) !p n. p n /\ (!m. m < n ==> ~p m) ==> (minimal) p = n !p. (?n. p n) <=> (?n. p n /\ (!m. m < n ==> ~p m)) !p. (?n. p n) <=> p ((minimal) p) /\ (!m. m < (minimal) p ==> ~p m) !p. (!n. (!m. m < n ==> p m) ==> p n) ==> (!n. p n) !m n. ~(m < n) <=> n <= m !m n. ~(m <= n) <=> n < m !m n. m <= n /\ n <= m <=> m = n !m n. m < n <=> m <= n /\ ~(m = n) !m n. SUC m < SUC n <=> m < n !m n. m <= n <=> m < n \/ m = n !m n. SUC m <= n <=> m < n !m n. SUC m <= SUC n <=> m <= n !m n. SUC m = SUC n <=> m = n !n p. MEM p (primes_below n) <=> prime p /\ p < n !n. ~(n < n) !n. ~(SUC n = _0) !n. BIT0 (SUC n) = SUC (SUC (BIT0 n)) !m. SUC m = m + 1 !s n. shd (sdrop s n) = snth s n !s n. stake s (SUC n) = APPEND (stake s n) [snth s n] BIT0 0 = 0 (minimal n. T) = 0
Constructive Lemmas	T !x h t. MEM x (CONS h t) <=> x = h \/ MEM x t !x y s. x IN y INSERT s <=> x = y \/ x IN s !t1 t2. (if F then t1 else t2) = t2 !t1 t2. (if T then t1 else t2) = t1 !x y. x = y <=> y = x !x y. x = y ==> y = x !e f. ?!fn. fn _0 = e /\ (!n. fn (SUC n) = f (fn n) n) !h t. set_of_list (CONS h t) = h INSERT set_of_list t !x s t. x INSERT s UNION t = x INSERT (s UNION t) !x s. x INSERT s = {y \| y = x \/ y IN s} !x s. {x} UNION s = x INSERT s !a. ?x. x = a !a. ?!x. x = a !x. ~(x IN {}) !x. ~MEM x [] !x. x = x !x. (@y. y = x) = x !p1 p2 q1 q2. (p1 ==> p2) /\ (q1 ==> q2) ==> p1 /\ q1 ==> p2 /\ q2 !p1 p2 q1 q2. (p1 ==> p2) /\ (q1 ==> q2) ==> p1 \/ q1 ==> p2 \/ q2 !p q r. p /\ (q \/ r) <=> p /\ q \/ p /\ r !t1 t2 t3. (t1 /\ t2) /\ t3 <=> t1 /\ t2 /\ t3 !t1 t2 t3. (t1 \/ t2) \/ t3 <=> t1 \/ t2 \/ t3 !t1 t2. ~(t1 /\ t2) <=> ~t1 \/ ~t2 !t1 t2. ~(t1 ==> t2) <=> t1 /\ ~t2 !t1 t2. ~(t1 \/ t2) <=> ~t1 /\ ~t2 !t1 t2. t1 \/ t2 <=> t2 \/ t1 !p q. (?x. p /\ q x) <=> p /\ (?x. q x) !p q. p /\ (?x. q x) <=> (?x. p /\ q x) !p q. p \/ (?x. q x) <=> (?x. p \/ q x) !t. (!x. t) <=> t !t. (?x. t) <=> t !t. ~ ~t <=> t !t. F /\ t <=> F !t. T /\ t <=> t !t. t /\ F <=> F !t. t /\ T <=> t !t. t /\ t <=> t !t. (F <=> t) <=> ~t !t. (T <=> t) <=> t !t. (t <=> F) <=> ~t !t. (t <=> T) <=> t !t. F ==> t <=> T !t. T ==> t <=> t !t. t ==> F <=> ~t !t. t ==> T <=> T !t. F \/ t <=> t !t. T \/ t <=> T !t. t \/ F <=> t !t. t \/ T <=> T !t. t \/ t <=> t !t. t ==> t !t. (t <=> T) \/ (t <=> F) !f y. (\x. f x) y = f y !f g. (!x. f x = g x) <=> f = g !f g. (!x. f x = g x) ==> f = g !f. ONE_ONE f <=> (!x1 x2. f x1 = f x2 ==> x1 = x2) !f. ONTO f <=> (!y. ?x. y = f x) !t. (\x. t x) = t !p a. (?x. a = x /\ p x) <=> p a !p x. x IN GSPEC p <=> p x !p x. x IN {y \| p y} <=> p x !p x. p x ==> p ((@) p) !p c x y. p (if c then x else y) <=> (c ==> p x) /\ (~c ==> p y) !p q. (?x. p x) /\ q <=> (?x. p x /\ q) !p q. (?x. p x) \/ q <=> (?x. p x \/ q) !p q. (!x. p x /\ q x) <=> (!x. p x) /\ (!x. q x) !p q. (?x. p x \/ q x) <=> (?x. p x) \/ (?x. q x) !p q. (?x. p x) \/ (?x. q x) <=> (?x. p x \/ q x) !p q. (!x. p x ==> q x) ==> (?x. p x) ==> (?x. q x) !p. (?x. ~p x) <=> ~(!x. p x) !p. (?!x. p x) <=> (?x. !y. p y <=> x = y) !p. (?!x. p x) <=> (?x. p x) /\ (!x x'. p x /\ p x' ==> x = x') !p. ~(!x. p x) <=> (?x. ~p x) !p. ~(?x. p x) <=> (!x. ~p x) !p. (!x y. p x y) <=> (!y x. p x y) !r. (!x. ?y. r x y) <=> (?f. !x. r x (f x)) !p. (!x. ?!y. p x y) <=> (?f. !x y. p x y <=> f x = y) !p. p [] /\ (!h t. p t ==> p (CONS h t)) ==> (!l. p l) !p n. p n /\ (!m. m < n ==> ~p m) ==> (minimal) p = n !p. (?n. p n) <=> (?n. p n /\ (!m. m < n ==> ~p m)) !p. (?n. p n) <=> p ((minimal) p) /\ (!m. m < (minimal) p ==> ~p m) !p. (!n. (!m. m < n ==> p m) ==> p n) ==> (!n. p n) !p. p _0 /\ (!n. p n ==> p (SUC n)) ==> (!n. p n) !l h t. APPEND (CONS h t) l = CONS h (APPEND t l) !l x. MEM x l <=> x IN set_of_list l !l1 l2 x. MEM x (APPEND l1 l2) <=> MEM x l1 \/ MEM x l2 !l1 l2. set_of_list (APPEND l1 l2) = set_of_list l1 UNION set_of_list l2 !l. APPEND [] l = l !l. APPEND l [] = l !m n. ~(m < n) <=> n <= m !m n. ~(m <= n) <=> n < m !m n. m <= n /\ n <= m <=> m = n !m n. m < n <=> m <= n /\ ~(m = n) !m n. m < SUC n <=> m <= n !m n. m < SUC n <=> m = n \/ m < n !m n. SUC m < SUC n <=> m < n !m n. m <= n <=> m < n \/ m = n !m n. m <= SUC n <=> m = SUC n \/ m <= n !m n. SUC m <= n <=> m < n !m n. SUC m <= SUC n <=> m <= n !m n. SUC m = SUC n <=> m = n !n p. MEM p (primes_below n) <=> prime p /\ p < n !m n. m + SUC n = SUC (m + n) !m n. SUC m + n = SUC (m + n) !n. ~(n < n) !m. ~(m < 0) !n. ~(SUC n = _0) !n. n < SUC n !n. 0 < SUC n !n. n <= n !n. 0 <= n !p. prime p <=> (?i. snth primes i = p) !m. m <= 0 <=> m = 0 !n. primes_below n = stake primes (minimal i. n <= snth primes i) !n. BIT0 (SUC n) = SUC (SUC (BIT0 n)) !n. BIT1 n = SUC (BIT0 n) !m. SUC m = m + 1 !m. m + 0 = m !n. 0 + n = n !s t x. x IN s UNION t <=> x IN s \/ x IN t !s t u. (s UNION t) UNION u = s UNION t UNION u !s t. (!x. x IN s <=> x IN t) <=> s = t !s t. s UNION t = {x \| x IN s \/ x IN t} !s t. s UNION t = t UNION s !s t. (!x. x IN s <=> x IN t) ==> s = t !s. {} UNION s = s !s. s UNION {} = s !s n. shd (sdrop s n) = snth s n !s n. stake s (SUC n) = APPEND (stake s n) [snth s n] !s n. stake s (SUC n) = CONS (shd s) (stake (stl s) n) !s n. sdrop s n = stream (\m. snth s (m + n)) !s. stake s 0 = [] !s. stream (snth s) = s ?f. ONE_ONE f /\ ~ONTO f F <=> (!p. p) T <=> (\p. p) = (\p. p) ~F <=> T ~T <=> F (~) = (\p. p ==> F) COND = (\t t1 t2. @x. ((t <=> T) ==> x = t1) /\ ((t <=> F) ==> x = t2)) (/\) = (\p q. (\f. f p q) = (\f. f T T)) (==>) = (\p q. p /\ q <=> p) (\/) = (\p q. !r. (p ==> r) ==> (q ==> r) ==> r) (!) = (\p. p = (\x. T)) (?) = (\p. !q. (!x. p x ==> q) ==> q) (?) = (\p. p ((@) p)) (?!) = (\p. (?) p /\ (!x y. p x /\ p y ==> x = y)) NUMERAL = (\n. n) BIT0 0 = 0 (minimal n. T) = 0 {} = {x \| F} set_of_list [] = {}
Contained Package	natural-prime
Comment	Natural-prime package from OpenTheory.

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