(************************************************************************) (* v * The Coq Proof Assistant / The Coq Development Team *) (* y. (************************************************) (** Properties of the injection from nat into Z *) Theorem inj_S : forall n:nat, Z_of_nat (S n) = Zsucc (Z_of_nat n). Proof. intro y; induction y as [| n H]; [ unfold Zsucc in |- *; simpl in |- *; trivial with arith | change (Zpos (Psucc (P_of_succ_nat n)) = Zsucc (Z_of_nat (S n))) in |- *; rewrite Zpos_succ_morphism; trivial with arith ]. Qed. Theorem inj_plus : forall n m:nat, Z_of_nat (n + m) = Z_of_nat n + Z_of_nat m. Proof. intro x; induction x as [| n H]; intro y; destruct y as [| m]; [ simpl in |- *; trivial with arith | simpl in |- *; trivial with arith | simpl in |- *; rewrite <- plus_n_O; trivial with arith | change (Z_of_nat (S (n + S m)) = Z_of_nat (S n) + Z_of_nat (S m)) in |- *; rewrite inj_S; rewrite H; do 2 rewrite inj_S; rewrite Zplus_succ_l; trivial with arith ]. Qed. Theorem inj_mult : forall n m:nat, Z_of_nat (n * m) = Z_of_nat n * Z_of_nat m. Proof. intro x; induction x as [| n H]; [ simpl in |- *; trivial with arith | intro y; rewrite inj_S; rewrite <- Zmult_succ_l_reverse; rewrite <- H; rewrite <- inj_plus; simpl in |- *; rewrite plus_comm; trivial with arith ]. Qed. Theorem inj_neq : forall n m:nat, neq n m -> Zne (Z_of_nat n) (Z_of_nat m). Proof. unfold neq, Zne, not in |- *; intros x y H1 H2; apply H1; generalize H2; case x; case y; intros; [ auto with arith | discriminate H0 | discriminate H0 | simpl in H0; injection H0; do 2 rewrite <- nat_of_P_o_P_of_succ_nat_eq_succ; intros E; rewrite E; auto with arith ]. Qed. Theorem inj_le : forall n m:nat, (n <= m)%nat -> Z_of_nat n <= Z_of_nat m. Proof. intros x y; intros H; elim H; [ unfold Zle in |- *; elim (Zcompare_Eq_iff_eq (Z_of_nat x) (Z_of_nat x)); intros H1 H2; rewrite H2; [ discriminate | trivial with arith ] | intros m H1 H2; apply Zle_trans with (Z_of_nat m); [ assumption | rewrite inj_S; apply Zle_succ ] ]. Qed. Theorem inj_lt : forall n m:nat, (n < m)%nat -> Z_of_nat n < Z_of_nat m. Proof. intros x y H; apply Zgt_lt; apply Zlt_succ_gt; rewrite <- inj_S; apply inj_le; exact H. Qed. Theorem inj_gt : forall n m:nat, (n > m)%nat -> Z_of_nat n > Z_of_nat m. Proof. intros x y H; apply Zlt_gt; apply inj_lt; exact H. Qed. Theorem inj_ge : forall n m:nat, (n >= m)%nat -> Z_of_nat n >= Z_of_nat m. Proof. intros x y H; apply Zle_ge; apply inj_le; apply H. Qed. Theorem inj_eq : forall n m:nat, n = m -> Z_of_nat n = Z_of_nat m. Proof. intros x y H; rewrite H; trivial with arith. Qed. Theorem intro_Z : forall n:nat, exists y : Z, Z_of_nat n = y /\ 0 <= y * 1 + 0. Proof. intros x; exists (Z_of_nat x); split; [ trivial with arith | rewrite Zmult_comm; rewrite Zmult_1_l; rewrite Zplus_0_r; unfold Zle in |- *; elim x; intros; simpl in |- *; discriminate ]. Qed. Theorem inj_minus1 : forall n m:nat, (m <= n)%nat -> Z_of_nat (n - m) = Z_of_nat n - Z_of_nat m. Proof. intros x y H; apply (Zplus_reg_l (Z_of_nat y)); unfold Zminus in |- *; rewrite Zplus_permute; rewrite Zplus_opp_r; rewrite <- inj_plus; rewrite <- (le_plus_minus y x H); rewrite Zplus_0_r; trivial with arith. Qed. Theorem inj_minus2 : forall n m:nat, (m > n)%nat -> Z_of_nat (n - m) = 0. Proof. intros x y H; rewrite not_le_minus_0; [ trivial with arith | apply gt_not_le; assumption ]. Qed. Theorem Zpos_eq_Z_of_nat_o_nat_of_P : forall p:positive, Zpos p = Z_of_nat (nat_of_P p). Proof. intros x; elim x; simpl in |- *; auto. intros p H; rewrite ZL6. apply f_equal with (f := Zpos). apply nat_of_P_inj. rewrite nat_of_P_o_P_of_succ_nat_eq_succ; unfold nat_of_P in |- *; simpl in |- *. rewrite ZL6; auto. intros p H; unfold nat_of_P in |- *; simpl in |- *. rewrite ZL6; simpl in |- *. rewrite inj_plus; repeat rewrite <- H. rewrite Zpos_xO; simpl in |- *; rewrite Pplus_diag; reflexivity. Qed.