220 lines
7.6 KiB
Text
220 lines
7.6 KiB
Text
/-
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Copyright (c) 2015 Jeremy Avigad. All rights reserved.
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Released under Apache 2.0 license as described in the file LICENSE.
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Author: Jeremy Avigad
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A proof that if n > 1 and a > 0, then the nth root of a is irrational, unless a is a perfect nth power.
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-/
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import data.rat .prime_factorization
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open eq.ops
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open algebra
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/- First, a textbook proof that sqrt 2 is irrational. -/
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section
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open nat
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theorem sqrt_two_irrational {a b : ℕ} (co : coprime a b) : a^2 ≠ 2 * b^2 :=
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assume H : a^2 = 2 * b^2,
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have even (a^2),
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from even_of_exists (exists.intro _ H),
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have even a,
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from even_of_even_pow this,
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obtain (c : nat) (aeq : a = 2 * c),
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from exists_of_even this,
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have 2 * (2 * c^2) = 2 * b^2,
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by rewrite [-H, aeq, *pow_two, algebra.mul.assoc, algebra.mul.left_comm c],
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have 2 * c^2 = b^2,
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from eq_of_mul_eq_mul_left dec_trivial this,
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have even (b^2),
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from even_of_exists (exists.intro _ (eq.symm this)),
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have even b,
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from even_of_even_pow this,
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assert 2 ∣ gcd a b,
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from dvd_gcd (dvd_of_even `even a`) (dvd_of_even `even b`),
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have 2 ∣ 1,
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begin rewrite [gcd_eq_one_of_coprime co at this], exact this end,
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show false, from absurd `2 ∣ 1` dec_trivial
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end
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/-
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Replacing 2 by an arbitrary prime and the power 2 by any n ≥ 1 yields the stronger result
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that the nth root of an integer is irrational, unless the integer is already a perfect nth
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power.
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-/
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section
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open nat decidable
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theorem root_irrational {a b c n : ℕ} (npos : n > 0) (apos : a > 0) (co : coprime a b)
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(H : a^n = c * b^n) : b = 1 :=
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have bpos : b > 0, from pos_of_ne_zero
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(suppose b = 0,
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have a^n = 0,
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by rewrite [H, this, zero_pow npos],
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assert a = 0,
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from eq_zero_of_pow_eq_zero this,
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show false,
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from ne_of_lt `0 < a` this⁻¹),
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have H₁ : ∀ p, prime p → ¬ p ∣ b, from
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take p,
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suppose prime p,
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suppose p ∣ b,
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assert p ∣ b^n,
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from dvd_pow_of_dvd_of_pos `p ∣ b` `n > 0`,
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have p ∣ a^n,
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by rewrite H; apply dvd_mul_of_dvd_right this,
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have p ∣ a,
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from dvd_of_prime_of_dvd_pow `prime p` this,
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have ¬ coprime a b,
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from not_coprime_of_dvd_of_dvd (gt_one_of_prime `prime p`) `p ∣ a` `p ∣ b`,
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show false,
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from this `coprime a b`,
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have blt2 : b < 2,
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from by_contradiction
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(suppose ¬ b < 2,
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have b ≥ 2,
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from le_of_not_gt this,
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obtain p [primep pdvdb],
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from exists_prime_and_dvd this,
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show false,
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from H₁ p primep pdvdb),
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show b = 1,
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from (le.antisymm (le_of_lt_succ blt2) (succ_le_of_lt bpos))
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end
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/-
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Here we state this in terms of the rationals, ℚ. The main difficulty is casting between ℕ, ℤ,
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and ℚ.
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-/
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section
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open rat int nat decidable
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theorem denom_eq_one_of_pow_eq {q : ℚ} {n : ℕ} {c : ℤ} (npos : n > 0) (H : q^n = c) :
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denom q = 1 :=
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let a := num q, b := denom q in
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have b ≠ 0,
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from ne_of_gt (denom_pos q),
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have bnz : b ≠ (0 : ℚ),
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from assume H, `b ≠ 0` (of_int.inj H),
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have bnnz : ((b : rat)^n ≠ 0),
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from assume bneqz, bnz (algebra.eq_zero_of_pow_eq_zero bneqz),
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have a^n /[rat] b^n = c,
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using bnz, begin rewrite [*of_int_pow, -algebra.div_pow, -eq_num_div_denom, -H] end,
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have (a^n : rat) = c *[rat] b^n,
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from eq.symm (!mul_eq_of_eq_div bnnz this⁻¹),
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have a^n = c * b^n, -- int version
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using this, by rewrite [-of_int_pow at this, -of_int_mul at this]; exact of_int.inj this,
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have (abs a)^n = abs c * (abs b)^n,
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using this, by rewrite [-abs_pow, this, abs_mul, abs_pow],
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have H₁ : (nat_abs a)^n = nat_abs c * (nat_abs b)^n,
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using this,
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begin apply int.of_nat.inj, rewrite [int.of_nat_mul, +int.of_nat_pow, +of_nat_nat_abs],
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exact this end,
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have H₂ : nat.coprime (nat_abs a) (nat_abs b),
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from of_nat.inj !coprime_num_denom,
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have nat_abs b = 1, from
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by_cases
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(suppose q = 0,
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by rewrite this)
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(suppose qne0 : q ≠ 0,
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using H₁ H₂, begin
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have ane0 : a ≠ 0, from
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suppose aeq0 : a = 0,
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have qeq0 : q = 0,
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by rewrite [eq_num_div_denom, aeq0, of_int_zero, algebra.zero_div],
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show false,
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from qne0 qeq0,
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have nat_abs a ≠ 0, from
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suppose nat_abs a = 0,
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have aeq0 : a = 0,
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from eq_zero_of_nat_abs_eq_zero this,
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show false, from ane0 aeq0,
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show nat_abs b = 1, from (root_irrational npos (pos_of_ne_zero this) H₂ H₁)
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end),
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show b = 1,
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using this, begin rewrite [-of_nat_nat_abs_of_nonneg (le_of_lt !denom_pos), this] end
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theorem eq_num_pow_of_pow_eq {q : ℚ} {n : ℕ} {c : ℤ} (npos : n > 0) (H : q^n = c) :
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c = (num q)^n :=
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have denom q = 1,
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from denom_eq_one_of_pow_eq npos H,
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have of_int c = of_int ((num q)^n), using this,
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by rewrite [-H, eq_num_div_denom q at {1}, this, of_int_one, div_one, of_int_pow],
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show c = (num q)^n , from of_int.inj this
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end
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/- As a corollary, for n > 1, the nth root of a prime is irrational. -/
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section
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open nat
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theorem not_eq_pow_of_prime {p n : ℕ} (a : ℕ) (ngt1 : n > 1) (primep : prime p) : p ≠ a^n :=
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assume peq : p = a^n,
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have npos : n > 0,
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from lt.trans dec_trivial ngt1,
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have pnez : p ≠ 0, from
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(suppose p = 0,
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show false,
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by let H := (pos_of_prime primep); rewrite this at H; exfalso; exact !lt.irrefl H),
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assert agtz : a > 0, from pos_of_ne_zero
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(suppose a = 0,
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show false, using npos pnez, by revert peq; rewrite [this, zero_pow npos]; exact pnez),
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have n * mult p a = 1, from calc
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n * mult p a = mult p (a^n) : begin rewrite [mult_pow n agtz primep] end
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... = mult p p : peq
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... = 1 : mult_self (gt_one_of_prime primep),
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have n ∣ 1,
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from dvd_of_mul_right_eq this,
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have n = 1,
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from eq_one_of_dvd_one this,
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show false, using this,
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by rewrite this at ngt1; exact !lt.irrefl ngt1
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open int rat
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theorem root_prime_irrational {p n : ℕ} {q : ℚ} (qnonneg : q ≥ 0) (ngt1 : n > 1)
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(primep : prime p) :
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q^n ≠ p :=
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have numq : num q ≥ 0, from num_nonneg_of_nonneg qnonneg,
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have npos : n > 0, from lt.trans dec_trivial ngt1,
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suppose q^n = p,
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have p = (num q)^n, from eq_num_pow_of_pow_eq npos this,
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have p = (nat_abs (num q))^n, using this numq,
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by apply of_nat.inj; rewrite [this, of_nat_pow, of_nat_nat_abs_of_nonneg numq],
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show false, from not_eq_pow_of_prime _ ngt1 primep this
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end
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/-
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Thaetetus, who lives in the fourth century BC, is said to have proved the irrationality of square
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roots up to seventeen. In Chapter 4 of /Why Prove it Again/, John Dawson notes that Thaetetus may
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have used an approach similar to the one below. (See data/nat/gcd.lean for the key theorem,
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"div_gcd_eq_div_gcd".)
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-/
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section
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open int
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example {a b c : ℤ} (co : coprime a b) (apos : a > 0) (bpos : b > 0)
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(H : a * a = c * (b * b)) :
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b = 1 :=
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assert H₁ : gcd (c * b) a = gcd c a,
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from gcd_mul_right_cancel_of_coprime _ (coprime_swap co),
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have a * a = c * b * b,
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by rewrite -mul.assoc at H; apply H,
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have a / (gcd a b) = c * b / gcd (c * b) a,
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from div_gcd_eq_div_gcd this bpos apos,
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have a = c * b / gcd c a, using this,
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by revert this; rewrite [↑coprime at co, co, int.div_one, H₁]; intros; assumption,
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have a = b * (c / gcd c a), using this,
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by revert this; rewrite [mul.comm, !int.mul_div_assoc !gcd_dvd_left]; intros; assumption,
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have b ∣ a,
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from dvd_of_mul_right_eq this⁻¹,
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have b ∣ gcd a b,
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from dvd_gcd this !dvd.refl,
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have b ∣ 1, using this,
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by rewrite [↑coprime at co, co at this]; apply this,
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show b = 1,
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from eq_one_of_dvd_one (le_of_lt bpos) this
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end
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