Library Coq.Init.Peano
The type nat of Peano natural numbers (built from O and S)
is defined in Datatypes.v
This module defines the following operations on natural numbers :
It states various lemmas and theorems about natural numbers,
including Peano's axioms of arithmetic (in Coq, these are provable).
Case analysis on nat and induction on nat * nat are provided too
- predecessor pred
- addition plus
- multiplication mult
- less or equal order le
- less lt
- greater or equal ge
- greater gt
Require Import Notations.
Require Import Ltac.
Require Import Datatypes.
Require Import Logic.
Require Coq.Init.Nat.
Open Scope nat_scope.
Definition eq_S := f_equal S.
Definition f_equal_nat := f_equal (A:=nat).
#[global]
Hint Resolve f_equal_nat: core.
The predecessor function
Notation pred := Nat.pred (only parsing).
Definition f_equal_pred := f_equal pred.
Theorem pred_Sn : forall n:nat, n = pred (S n).
Injectivity of successor
Definition eq_add_S n m (H: S n = S m): n = m := f_equal pred H.
#[global]
Hint Immediate eq_add_S: core.
Theorem not_eq_S : forall n m:nat, n <> m -> S n <> S m.
#[global]
Hint Resolve not_eq_S: core.
Definition IsSucc (n:nat) : Prop :=
match n with
| O => False
| S p => True
end.
Zero is not the successor of a number
Theorem O_S : forall n:nat, 0 <> S n.
#[global]
Hint Resolve O_S: core.
Theorem n_Sn : forall n:nat, n <> S n.
#[global]
Hint Resolve n_Sn: core.
Addition
Notation plus := Nat.add (only parsing).
Infix "+" := Nat.add : nat_scope.
Definition f_equal2_plus := f_equal2 plus.
Definition f_equal2_nat := f_equal2 (A1:=nat) (A2:=nat).
#[global]
Hint Resolve f_equal2_nat: core.
Lemma plus_n_O : forall n:nat, n = n + 0.
#[global]
Remove Hints eq_refl : core.
#[global]
Hint Resolve plus_n_O eq_refl: core.
Lemma plus_O_n : forall n:nat, 0 + n = n.
Lemma plus_n_Sm : forall n m:nat, S (n + m) = n + S m.
#[global]
Hint Resolve plus_n_Sm: core.
Lemma plus_Sn_m : forall n m:nat, S n + m = S (n + m).
Standard associated names
Notation plus_0_r_reverse := plus_n_O (only parsing).
Notation plus_succ_r_reverse := plus_n_Sm (only parsing).
Multiplication
Notation mult := Nat.mul (only parsing).
Infix "*" := Nat.mul : nat_scope.
Definition f_equal2_mult := f_equal2 mult.
#[global]
Hint Resolve f_equal2_mult: core.
Lemma mult_n_O : forall n:nat, 0 = n * 0.
#[global]
Hint Resolve mult_n_O: core.
Lemma mult_n_Sm : forall n m:nat, n * m + n = n * S m.
#[global]
Hint Resolve mult_n_Sm: core.
Standard associated names
Notation mult_0_r_reverse := mult_n_O (only parsing).
Notation mult_succ_r_reverse := mult_n_Sm (only parsing).
Truncated subtraction: m-n is 0 if n>=m
Definition of the usual orders, the basic properties of le and lt
can be found in files Le and Lt
Inductive le (n:nat) : nat -> Prop :=
| le_n : n <= n
| le_S : forall m:nat, n <= m -> n <= S m
where "n <= m" := (le n m) : nat_scope.
Register le_n as num.nat.le_n.
#[global]
Hint Constructors le: core.
Definition lt (n m:nat) := S n <= m.
#[global]
Hint Unfold lt: core.
Infix "<" := lt : nat_scope.
Definition ge (n m:nat) := m <= n.
#[global]
Hint Unfold ge: core.
Infix ">=" := ge : nat_scope.
Definition gt (n m:nat) := m < n.
#[global]
Hint Unfold gt: core.
Infix ">" := gt : nat_scope.
Notation "x <= y <= z" := (x <= y /\ y <= z) : nat_scope.
Notation "x <= y < z" := (x <= y /\ y < z) : nat_scope.
Notation "x < y < z" := (x < y /\ y < z) : nat_scope.
Notation "x < y <= z" := (x < y /\ y <= z) : nat_scope.
Register le as num.nat.le.
Register lt as num.nat.lt.
Register ge as num.nat.ge.
Register gt as num.nat.gt.
Theorem le_pred : forall n m, n <= m -> pred n <= pred m.
Theorem le_S_n : forall n m, S n <= S m -> n <= m.
Theorem le_0_n : forall n, 0 <= n.
Theorem le_n_S : forall n m, n <= m -> S n <= S m.
Case analysis
Principle of double induction
Theorem nat_double_ind :
forall R:nat -> nat -> Prop,
(forall n:nat, R 0 n) ->
(forall n:nat, R (S n) 0) ->
(forall n m:nat, R n m -> R (S n) (S m)) -> forall n m:nat, R n m.
Maximum and minimum : definitions and specifications
Notation max := Nat.max (only parsing).
Notation min := Nat.min (only parsing).
Lemma max_l n m : m <= n -> Nat.max n m = n.
Lemma max_r n m : n <= m -> Nat.max n m = m.
Lemma min_l n m : n <= m -> Nat.min n m = n.
Lemma min_r n m : m <= n -> Nat.min n m = m.
Lemma nat_rect_succ_r {A} (f: A -> A) (x:A) n :
nat_rect (fun _ => A) x (fun _ => f) (S n) = nat_rect (fun _ => A) (f x) (fun _ => f) n.
Theorem nat_rect_plus :
forall (n m:nat) {A} (f:A -> A) (x:A),
nat_rect (fun _ => A) x (fun _ => f) (n + m) =
nat_rect (fun _ => A) (nat_rect (fun _ => A) x (fun _ => f) m) (fun _ => f) n.