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Diffstat (limited to 'theories/Numbers/NatInt/NZAddOrder.v')
| -rw-r--r-- | theories/Numbers/NatInt/NZAddOrder.v | 166 |
1 files changed, 166 insertions, 0 deletions
diff --git a/theories/Numbers/NatInt/NZAddOrder.v b/theories/Numbers/NatInt/NZAddOrder.v new file mode 100644 index 00000000..50d1c42f --- /dev/null +++ b/theories/Numbers/NatInt/NZAddOrder.v @@ -0,0 +1,166 @@ +(************************************************************************) +(* 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 *) +(************************************************************************) +(* Evgeny Makarov, INRIA, 2007 *) +(************************************************************************) + +(*i $Id: NZAddOrder.v 11040 2008-06-03 00:04:16Z letouzey $ i*) + +Require Import NZAxioms. +Require Import NZOrder. + +Module NZAddOrderPropFunct (Import NZOrdAxiomsMod : NZOrdAxiomsSig). +Module Export NZOrderPropMod := NZOrderPropFunct NZOrdAxiomsMod. +Open Local Scope NatIntScope. + +Theorem NZadd_lt_mono_l : forall n m p : NZ, n < m <-> p + n < p + m. +Proof. +intros n m p; NZinduct p. +now do 2 rewrite NZadd_0_l. +intro p. do 2 rewrite NZadd_succ_l. now rewrite <- NZsucc_lt_mono. +Qed. + +Theorem NZadd_lt_mono_r : forall n m p : NZ, n < m <-> n + p < m + p. +Proof. +intros n m p. +rewrite (NZadd_comm n p); rewrite (NZadd_comm m p); apply NZadd_lt_mono_l. +Qed. + +Theorem NZadd_lt_mono : forall n m p q : NZ, n < m -> p < q -> n + p < m + q. +Proof. +intros n m p q H1 H2. +apply NZlt_trans with (m + p); +[now apply -> NZadd_lt_mono_r | now apply -> NZadd_lt_mono_l]. +Qed. + +Theorem NZadd_le_mono_l : forall n m p : NZ, n <= m <-> p + n <= p + m. +Proof. +intros n m p; NZinduct p. +now do 2 rewrite NZadd_0_l. +intro p. do 2 rewrite NZadd_succ_l. now rewrite <- NZsucc_le_mono. +Qed. + +Theorem NZadd_le_mono_r : forall n m p : NZ, n <= m <-> n + p <= m + p. +Proof. +intros n m p. +rewrite (NZadd_comm n p); rewrite (NZadd_comm m p); apply NZadd_le_mono_l. +Qed. + +Theorem NZadd_le_mono : forall n m p q : NZ, n <= m -> p <= q -> n + p <= m + q. +Proof. +intros n m p q H1 H2. +apply NZle_trans with (m + p); +[now apply -> NZadd_le_mono_r | now apply -> NZadd_le_mono_l]. +Qed. + +Theorem NZadd_lt_le_mono : forall n m p q : NZ, n < m -> p <= q -> n + p < m + q. +Proof. +intros n m p q H1 H2. +apply NZlt_le_trans with (m + p); +[now apply -> NZadd_lt_mono_r | now apply -> NZadd_le_mono_l]. +Qed. + +Theorem NZadd_le_lt_mono : forall n m p q : NZ, n <= m -> p < q -> n + p < m + q. +Proof. +intros n m p q H1 H2. +apply NZle_lt_trans with (m + p); +[now apply -> NZadd_le_mono_r | now apply -> NZadd_lt_mono_l]. +Qed. + +Theorem NZadd_pos_pos : forall n m : NZ, 0 < n -> 0 < m -> 0 < n + m. +Proof. +intros n m H1 H2. rewrite <- (NZadd_0_l 0). now apply NZadd_lt_mono. +Qed. + +Theorem NZadd_pos_nonneg : forall n m : NZ, 0 < n -> 0 <= m -> 0 < n + m. +Proof. +intros n m H1 H2. rewrite <- (NZadd_0_l 0). now apply NZadd_lt_le_mono. +Qed. + +Theorem NZadd_nonneg_pos : forall n m : NZ, 0 <= n -> 0 < m -> 0 < n + m. +Proof. +intros n m H1 H2. rewrite <- (NZadd_0_l 0). now apply NZadd_le_lt_mono. +Qed. + +Theorem NZadd_nonneg_nonneg : forall n m : NZ, 0 <= n -> 0 <= m -> 0 <= n + m. +Proof. +intros n m H1 H2. rewrite <- (NZadd_0_l 0). now apply NZadd_le_mono. +Qed. + +Theorem NZlt_add_pos_l : forall n m : NZ, 0 < n -> m < n + m. +Proof. +intros n m H. apply -> (NZadd_lt_mono_r 0 n m) in H. +now rewrite NZadd_0_l in H. +Qed. + +Theorem NZlt_add_pos_r : forall n m : NZ, 0 < n -> m < m + n. +Proof. +intros; rewrite NZadd_comm; now apply NZlt_add_pos_l. +Qed. + +Theorem NZle_lt_add_lt : forall n m p q : NZ, n <= m -> p + m < q + n -> p < q. +Proof. +intros n m p q H1 H2. destruct (NZle_gt_cases q p); [| assumption]. +pose proof (NZadd_le_mono q p n m H H1) as H3. apply <- NZnle_gt in H2. +false_hyp H3 H2. +Qed. + +Theorem NZlt_le_add_lt : forall n m p q : NZ, n < m -> p + m <= q + n -> p < q. +Proof. +intros n m p q H1 H2. destruct (NZle_gt_cases q p); [| assumption]. +pose proof (NZadd_le_lt_mono q p n m H H1) as H3. apply <- NZnle_gt in H3. +false_hyp H2 H3. +Qed. + +Theorem NZle_le_add_le : forall n m p q : NZ, n <= m -> p + m <= q + n -> p <= q. +Proof. +intros n m p q H1 H2. destruct (NZle_gt_cases p q); [assumption |]. +pose proof (NZadd_lt_le_mono q p n m H H1) as H3. apply <- NZnle_gt in H3. +false_hyp H2 H3. +Qed. + +Theorem NZadd_lt_cases : forall n m p q : NZ, n + m < p + q -> n < p \/ m < q. +Proof. +intros n m p q H; +destruct (NZle_gt_cases p n) as [H1 | H1]. +destruct (NZle_gt_cases q m) as [H2 | H2]. +pose proof (NZadd_le_mono p n q m H1 H2) as H3. apply -> NZle_ngt in H3. +false_hyp H H3. +now right. now left. +Qed. + +Theorem NZadd_le_cases : forall n m p q : NZ, n + m <= p + q -> n <= p \/ m <= q. +Proof. +intros n m p q H. +destruct (NZle_gt_cases n p) as [H1 | H1]. now left. +destruct (NZle_gt_cases m q) as [H2 | H2]. now right. +assert (H3 : p + q < n + m) by now apply NZadd_lt_mono. +apply -> NZle_ngt in H. false_hyp H3 H. +Qed. + +Theorem NZadd_neg_cases : forall n m : NZ, n + m < 0 -> n < 0 \/ m < 0. +Proof. +intros n m H; apply NZadd_lt_cases; now rewrite NZadd_0_l. +Qed. + +Theorem NZadd_pos_cases : forall n m : NZ, 0 < n + m -> 0 < n \/ 0 < m. +Proof. +intros n m H; apply NZadd_lt_cases; now rewrite NZadd_0_l. +Qed. + +Theorem NZadd_nonpos_cases : forall n m : NZ, n + m <= 0 -> n <= 0 \/ m <= 0. +Proof. +intros n m H; apply NZadd_le_cases; now rewrite NZadd_0_l. +Qed. + +Theorem NZadd_nonneg_cases : forall n m : NZ, 0 <= n + m -> 0 <= n \/ 0 <= m. +Proof. +intros n m H; apply NZadd_le_cases; now rewrite NZadd_0_l. +Qed. + +End NZAddOrderPropFunct. + |