diff options
author | Samuel Mimram <samuel.mimram@ens-lyon.org> | 2004-07-28 21:54:47 +0000 |
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committer | Samuel Mimram <samuel.mimram@ens-lyon.org> | 2004-07-28 21:54:47 +0000 |
commit | 6b649aba925b6f7462da07599fe67ebb12a3460e (patch) | |
tree | 43656bcaa51164548f3fa14e5b10de5ef1088574 /theories/ZArith/Zabs.v |
Imported Upstream version 8.0pl1upstream/8.0pl1
Diffstat (limited to 'theories/ZArith/Zabs.v')
-rw-r--r-- | theories/ZArith/Zabs.v | 128 |
1 files changed, 128 insertions, 0 deletions
diff --git a/theories/ZArith/Zabs.v b/theories/ZArith/Zabs.v new file mode 100644 index 00000000..90e4c2a4 --- /dev/null +++ b/theories/ZArith/Zabs.v @@ -0,0 +1,128 @@ +(************************************************************************) +(* v * The Coq Proof Assistant / The Coq Development Team *) +(* <O___,, * CNRS-Ecole Polytechnique-INRIA Futurs-Universite Paris Sud *) +(* \VV/ **************************************************************) +(* // * This file is distributed under the terms of the *) +(* * GNU Lesser General Public License Version 2.1 *) +(************************************************************************) +(*i $Id: Zabs.v,v 1.4.2.1 2004/07/16 19:31:21 herbelin Exp $ i*) + +(** Binary Integers (Pierre Crégut (CNET, Lannion, France) *) + +Require Import Arith. +Require Import BinPos. +Require Import BinInt. +Require Import Zorder. +Require Import ZArith_dec. + +Open Local Scope Z_scope. + +(**********************************************************************) +(** Properties of absolute value *) + +Lemma Zabs_eq : forall n:Z, 0 <= n -> Zabs n = n. +intro x; destruct x; auto with arith. +compute in |- *; intros; absurd (Gt = Gt); trivial with arith. +Qed. + +Lemma Zabs_non_eq : forall n:Z, n <= 0 -> Zabs n = - n. +Proof. +intro x; destruct x; auto with arith. +compute in |- *; intros; absurd (Gt = Gt); trivial with arith. +Qed. + +Theorem Zabs_Zopp : forall n:Z, Zabs (- n) = Zabs n. +Proof. +intros z; case z; simpl in |- *; auto. +Qed. + +(** Proving a property of the absolute value by cases *) + +Lemma Zabs_ind : + forall (P:Z -> Prop) (n:Z), + (n >= 0 -> P n) -> (n <= 0 -> P (- n)) -> P (Zabs n). +Proof. +intros P x H H0; elim (Z_lt_ge_dec x 0); intro. +assert (x <= 0). apply Zlt_le_weak; assumption. +rewrite Zabs_non_eq. apply H0. assumption. assumption. +rewrite Zabs_eq. apply H; assumption. apply Zge_le. assumption. +Qed. + +Theorem Zabs_intro : forall P (n:Z), P (- n) -> P n -> P (Zabs n). +intros P z; case z; simpl in |- *; auto. +Qed. + +Definition Zabs_dec : forall x:Z, {x = Zabs x} + {x = - Zabs x}. +Proof. +intro x; destruct x; auto with arith. +Defined. + +Lemma Zabs_pos : forall n:Z, 0 <= Zabs n. +intro x; destruct x; auto with arith; compute in |- *; intros H; inversion H. +Qed. + +Theorem Zabs_eq_case : forall n m:Z, Zabs n = Zabs m -> n = m \/ n = - m. +Proof. +intros z1 z2; case z1; case z2; simpl in |- *; auto; + try (intros; discriminate); intros p1 p2 H1; injection H1; + (intros H2; rewrite H2); auto. +Qed. + +(** Triangular inequality *) + +Hint Local Resolve Zle_neg_pos: zarith. + +Theorem Zabs_triangle : forall n m:Z, Zabs (n + m) <= Zabs n + Zabs m. +Proof. +intros z1 z2; case z1; case z2; try (simpl in |- *; auto with zarith; fail). +intros p1 p2; + apply Zabs_intro with (P := fun x => x <= Zabs (Zpos p2) + Zabs (Zneg p1)); + try rewrite Zopp_plus_distr; auto with zarith. +apply Zplus_le_compat; simpl in |- *; auto with zarith. +apply Zplus_le_compat; simpl in |- *; auto with zarith. +intros p1 p2; + apply Zabs_intro with (P := fun x => x <= Zabs (Zpos p2) + Zabs (Zneg p1)); + try rewrite Zopp_plus_distr; auto with zarith. +apply Zplus_le_compat; simpl in |- *; auto with zarith. +apply Zplus_le_compat; simpl in |- *; auto with zarith. +Qed. + +(** Absolute value and multiplication *) + +Lemma Zsgn_Zabs : forall n:Z, n * Zsgn n = Zabs n. +Proof. +intro x; destruct x; rewrite Zmult_comm; auto with arith. +Qed. + +Lemma Zabs_Zsgn : forall n:Z, Zabs n * Zsgn n = n. +Proof. +intro x; destruct x; rewrite Zmult_comm; auto with arith. +Qed. + +Theorem Zabs_Zmult : forall n m:Z, Zabs (n * m) = Zabs n * Zabs m. +Proof. +intros z1 z2; case z1; case z2; simpl in |- *; auto. +Qed. + +(** absolute value in nat is compatible with order *) + +Lemma Zabs_nat_lt : + forall n m:Z, 0 <= n /\ n < m -> (Zabs_nat n < Zabs_nat m)%nat. +Proof. +intros x y. case x; simpl in |- *. case y; simpl in |- *. + +intro. absurd (0 < 0). compute in |- *. intro H0. discriminate H0. intuition. +intros. elim (ZL4 p). intros. rewrite H0. auto with arith. +intros. elim (ZL4 p). intros. rewrite H0. auto with arith. + +case y; simpl in |- *. +intros. absurd (Zpos p < 0). compute in |- *. intro H0. discriminate H0. intuition. +intros. change (nat_of_P p > nat_of_P p0)%nat in |- *. +apply nat_of_P_gt_Gt_compare_morphism. +elim H; auto with arith. intro. exact (ZC2 p0 p). + +intros. absurd (Zpos p0 < Zneg p). +compute in |- *. intro H0. discriminate H0. intuition. + +intros. absurd (0 <= Zneg p). compute in |- *. auto with arith. intuition. +Qed.
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