Definitions of basic functions #

theorem Int.subNatNat_elim (m : Nat) (n : Nat) (motive : Nat → Nat → Int → Prop) (hp : ∀ (i n : Nat), motive (n + i) n ↑i) (hn : ∀ (i m : Nat), motive m (m + i + 1) (Int.negSucc i)) :

motive m n (Int.subNatNat m n)

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theorem Int.subNatNat_add_left {m : Nat} {n : Nat} :

Int.subNatNat (m + n) m = ↑n

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theorem Int.subNatNat_add_right {m : Nat} {n : Nat} :

Int.subNatNat m (m + n + 1) = Int.negSucc n

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theorem Int.subNatNat_add_add (m : Nat) (n : Nat) (k : Nat) :

Int.subNatNat (m + k) (n + k) = Int.subNatNat m n

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theorem Int.subNatNat_of_le {m : Nat} {n : Nat} (h : n ≤ m) :

Int.subNatNat m n = ↑(m - n)

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theorem Int.subNatNat_of_lt {m : Nat} {n : Nat} (h : m < n) :

Int.subNatNat m n = Int.negSucc (Nat.pred (n - m))

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theorem Int.add_comm (a : Int) (b : Int) :

a + b = b + a

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@[simp]

theorem Int.add_zero (a : Int) :

a + 0 = a

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@[simp]

theorem Int.zero_add (a : Int) :

0 + a = a

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theorem Int.ofNat_add_negSucc_of_lt {m : Nat} {n : Nat} (h : m < Nat.succ n) :

Int.ofNat m + Int.negSucc n = Int.negSucc (n - m)

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theorem Int.subNatNat_sub {n : Nat} {m : Nat} (h : n ≤ m) (k : Nat) :

Int.subNatNat (m - n) k = Int.subNatNat m (k + n)

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theorem Int.subNatNat_add (m : Nat) (n : Nat) (k : Nat) :

Int.subNatNat (m + n) k = ↑m + Int.subNatNat n k

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theorem Int.subNatNat_add_negSucc (m : Nat) (n : Nat) (k : Nat) :

Int.subNatNat m n + Int.negSucc k = Int.subNatNat m (n + Nat.succ k)

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theorem Int.add_assoc (a : Int) (b : Int) (c : Int) :

a + b + c = a + (b + c)

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theorem Int.add_assoc.aux1 (m : Nat) (n : Nat) (c : Int) :

↑m + ↑n + c = ↑m + (↑n + c)

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theorem Int.add_assoc.aux2 (m : Nat) (n : Nat) (k : Nat) :

Int.negSucc m + Int.negSucc n + ↑k = Int.negSucc m + (Int.negSucc n + ↑k)

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theorem Int.add_left_comm (a : Int) (b : Int) (c : Int) :

a + (b + c) = b + (a + c)

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theorem Int.add_right_comm (a : Int) (b : Int) (c : Int) :

a + b + c = a + c + b

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theorem Int.subNatNat_self (n : Nat) :

Int.subNatNat n n = 0

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theorem Int.add_left_neg (a : Int) :

-a + a = 0

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theorem Int.add_right_neg (a : Int) :

a + -a = 0

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@[simp]

theorem Int.neg_eq_of_add_eq_zero {a : Int} {b : Int} (h : a + b = 0) :

-a = b

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theorem Int.eq_neg_of_eq_neg {a : Int} {b : Int} (h : a = -b) :

b = -a

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theorem Int.eq_neg_comm {a : Int} {b : Int} :

a = -b ↔ b = -a

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theorem Int.neg_eq_comm {a : Int} {b : Int} :

-a = b ↔ -b = a

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theorem Int.neg_add_cancel_left (a : Int) (b : Int) :

-a + (a + b) = b

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theorem Int.add_neg_cancel_left (a : Int) (b : Int) :

a + (-a + b) = b

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theorem Int.add_neg_cancel_right (a : Int) (b : Int) :

a + b + -b = a

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theorem Int.neg_add_cancel_right (a : Int) (b : Int) :

a + -b + b = a

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theorem Int.add_left_cancel {a : Int} {b : Int} {c : Int} (h : a + b = a + c) :

b = c

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theorem Int.neg_add {a : Int} {b : Int} :

-(a + b) = -a + -b

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@[simp]

theorem Int.negSucc_sub_one (n : Nat) :

Int.negSucc n - 1 = Int.negSucc (n + 1)

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@[simp]

theorem Int.sub_self (a : Int) :

a - a = 0

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@[simp]

theorem Int.sub_zero (a : Int) :

a - 0 = a

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@[simp]

theorem Int.zero_sub (a : Int) :

0 - a = -a

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theorem Int.sub_eq_zero_of_eq {a : Int} {b : Int} (h : a = b) :

a - b = 0

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theorem Int.eq_of_sub_eq_zero {a : Int} {b : Int} (h : a - b = 0) :

a = b

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theorem Int.sub_eq_zero {a : Int} {b : Int} :

a - b = 0 ↔ a = b

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theorem Int.sub_sub (a : Int) (b : Int) (c : Int) :

a - b - c = a - (b + c)

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theorem Int.neg_sub (a : Int) (b : Int) :

-(a - b) = b - a

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theorem Int.sub_sub_self (a : Int) (b : Int) :

a - (a - b) = b

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theorem Int.sub_neg (a : Int) (b : Int) :

a - -b = a + b

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@[simp]

theorem Int.sub_add_cancel (a : Int) (b : Int) :

a - b + b = a

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@[simp]

theorem Int.add_sub_cancel (a : Int) (b : Int) :

a + b - b = a

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theorem Int.add_sub_assoc (a : Int) (b : Int) (c : Int) :

a + b - c = a + (b - c)

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theorem Int.ofNat_sub {m : Nat} {n : Nat} (h : m ≤ n) :

↑(n - m) = ↑n - ↑m

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theorem Int.negSucc_coe' (n : Nat) :

Int.negSucc n = -↑n - 1

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theorem Int.subNatNat_eq_coe {m : Nat} {n : Nat} :

Int.subNatNat m n = ↑m - ↑n

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theorem Int.toNat_sub (m : Nat) (n : Nat) :

Int.toNat (↑m - ↑n) = m - n

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@[simp]

theorem Int.add_right_inj (i : Int) (j : Int) (k : Int) :

i + k = j + k ↔ i = j

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@[simp]

theorem Int.add_left_inj (i : Int) (j : Int) (k : Int) :

k + i = k + j ↔ i = j

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@[simp]

theorem Int.sub_left_inj (i : Int) (j : Int) (k : Int) :

k - i = k - j ↔ i = j

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@[simp]

theorem Int.sub_right_inj (i : Int) (j : Int) (k : Int) :

i - k = j - k ↔ i = j

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@[simp]

theorem Int.ofNat_mul_negSucc (m : Nat) (n : Nat) :

↑m * Int.negSucc n = -↑(m * Nat.succ n)

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@[simp]

theorem Int.negSucc_mul_ofNat (m : Nat) (n : Nat) :

Int.negSucc m * ↑n = -↑(Nat.succ m * n)

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@[simp]

theorem Int.negSucc_mul_negSucc (m : Nat) (n : Nat) :

Int.negSucc m * Int.negSucc n = ↑(Nat.succ m) * ↑(Nat.succ n)

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theorem Int.mul_comm (a : Int) (b : Int) :

a * b = b * a

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theorem Int.ofNat_mul_negOfNat (m : Nat) (n : Nat) :

↑m * Int.negOfNat n = Int.negOfNat (m * n)

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theorem Int.negOfNat_mul_ofNat (m : Nat) (n : Nat) :

Int.negOfNat m * ↑n = Int.negOfNat (m * n)

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theorem Int.negSucc_mul_negOfNat (m : Nat) (n : Nat) :

Int.negSucc m * Int.negOfNat n = Int.ofNat (Nat.succ m * n)

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theorem Int.negOfNat_mul_negSucc (m : Nat) (n : Nat) :

Int.negOfNat n * Int.negSucc m = Int.ofNat (n * Nat.succ m)

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theorem Int.mul_assoc (a : Int) (b : Int) (c : Int) :

a * b * c = a * (b * c)

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theorem Int.mul_left_comm (a : Int) (b : Int) (c : Int) :

a * (b * c) = b * (a * c)

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theorem Int.mul_right_comm (a : Int) (b : Int) (c : Int) :

a * b * c = a * c * b

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@[simp]

theorem Int.mul_zero (a : Int) :

a * 0 = 0

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@[simp]

theorem Int.zero_mul (a : Int) :

0 * a = 0

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theorem Int.negOfNat_eq_subNatNat_zero (n : Nat) :

Int.negOfNat n = Int.subNatNat 0 n

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theorem Int.ofNat_mul_subNatNat (m : Nat) (n : Nat) (k : Nat) :

↑m * Int.subNatNat n k = Int.subNatNat (m * n) (m * k)

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theorem Int.negOfNat_add (m : Nat) (n : Nat) :

Int.negOfNat m + Int.negOfNat n = Int.negOfNat (m + n)

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theorem Int.negSucc_mul_subNatNat (m : Nat) (n : Nat) (k : Nat) :

Int.negSucc m * Int.subNatNat n k = Int.subNatNat (Nat.succ m * k) (Nat.succ m * n)

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theorem Int.mul_add (a : Int) (b : Int) (c : Int) :

a * (b + c) = a * b + a * c

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theorem Int.add_mul (a : Int) (b : Int) (c : Int) :

(a + b) * c = a * c + b * c

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theorem Int.neg_mul_eq_neg_mul (a : Int) (b : Int) :

-(a * b) = -a * b

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theorem Int.neg_mul_eq_mul_neg (a : Int) (b : Int) :

-(a * b) = a * -b

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theorem Int.neg_mul (a : Int) (b : Int) :

-a * b = -(a * b)

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theorem Int.mul_neg (a : Int) (b : Int) :

a * -b = -(a * b)

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theorem Int.neg_mul_neg (a : Int) (b : Int) :

-a * -b = a * b

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theorem Int.neg_mul_comm (a : Int) (b : Int) :

-a * b = a * -b

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theorem Int.mul_sub (a : Int) (b : Int) (c : Int) :

a * (b - c) = a * b - a * c

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theorem Int.sub_mul (a : Int) (b : Int) (c : Int) :

(a - b) * c = a * c - b * c

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@[simp]

theorem Int.one_mul (a : Int) :

1 * a = a

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@[simp]

theorem Int.mul_one (a : Int) :

a * 1 = a

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theorem Int.mul_neg_one (a : Int) :

a * -1 = -a

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theorem Int.neg_eq_neg_one_mul (a : Int) :

-a = -1 * a

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theorem Int.mul_eq_zero {a : Int} {b : Int} :

a * b = 0 ↔ a = 0 ∨ b = 0

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theorem Int.mul_ne_zero {a : Int} {b : Int} (a0 : a ≠ 0) (b0 : b ≠ 0) :

a * b ≠ 0

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theorem Int.eq_of_mul_eq_mul_right {a : Int} {b : Int} {c : Int} (ha : a ≠ 0) (h : b * a = c * a) :

b = c

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theorem Int.eq_of_mul_eq_mul_left {a : Int} {b : Int} {c : Int} (ha : a ≠ 0) (h : a * b = a * c) :

b = c

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theorem Int.mul_eq_mul_left_iff {a : Int} {b : Int} {c : Int} (h : c ≠ 0) :

c * a = c * b ↔ a = b

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theorem Int.mul_eq_mul_right_iff {a : Int} {b : Int} {c : Int} (h : c ≠ 0) :

a * c = b * c ↔ a = b

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theorem Int.eq_one_of_mul_eq_self_left {a : Int} {b : Int} (Hpos : a ≠ 0) (H : b * a = a) :

b = 1

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theorem Int.eq_one_of_mul_eq_self_right {a : Int} {b : Int} (Hpos : b ≠ 0) (H : b * a = b) :

a = 1

pow #

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theorem Int.pow_zero (b : Int) :

b ^ 0 = 1

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theorem Int.pow_succ (b : Int) (e : Nat) :

b ^ (e + 1) = b ^ e * b

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theorem Int.pow_succ' (b : Int) (e : Nat) :

b ^ (e + 1) = b * b ^ e

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theorem Int.pow_le_pow_of_le_left {n : Nat} {m : Nat} (h : n ≤ m) (i : Nat) :

n ^ i ≤ m ^ i

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theorem Int.pow_le_pow_of_le_right {n : Nat} (hx : n > 0) {i : Nat} {j : Nat} :

i ≤ j → n ^ i ≤ n ^ j

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theorem Int.pos_pow_of_pos {n : Nat} (m : Nat) (h : 0 < n) :

0 < n ^ m

NatCast lemmas

The following lemmas are later subsumed by e.g. Nat.cast_add and Nat.cast_mul in Mathlib but it is convenient to have these earlier, for users who only need Nat and Int.

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theorem Int.natCast_zero :

↑0 = 0

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theorem Int.natCast_one :

↑1 = 1

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@[simp]

theorem Int.natCast_add (a : Nat) (b : Nat) :

↑(a + b) = ↑a + ↑b

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@[simp]