-(**************************************************************************)
-(* ___ *)
-(* ||M|| *)
-(* ||A|| A project by Andrea Asperti *)
-(* ||T|| *)
-(* ||I|| Developers: *)
-(* ||T|| The HELM team. *)
-(* ||A|| http://helm.cs.unibo.it *)
-(* \ / *)
-(* \ / This file is distributed under the terms of the *)
-(* v GNU General Public License Version 2 *)
-(* *)
-(**************************************************************************)
-
-
-
-include "NPlus/fun.ma".
-
-(* Monoidal properties ******************************************************)
-
-theorem nplus_zero_1: ∀q. zero ⊕ q ≍ q.
- intros; elim q; clear q; autobatch.
-qed.
-
-theorem nplus_succ_1: ∀p,q,r. p ⊕ q ≍ r → succ p ⊕ q ≍ succ r.
- intros; elim H; clear H q r; autobatch.
-qed.
-
-theorem nplus_comm: ∀p, q, x. p ⊕ q ≍ x → ∀y. q ⊕ p ≍ y → x = y.
- intros 4; elim H; clear H q x;
- [ lapply linear nplus_inv_zero_1 to H1
- | lapply linear nplus_inv_succ_1 to H3. decompose
- ]; destruct; autobatch.
-qed.
-
-theorem nplus_comm_rew: ∀p,q,r. p ⊕ q ≍ r → q ⊕ p ≍ r.
- intros; elim H; clear H q r; autobatch.
-qed.
-
-theorem nplus_ass: ∀p1, p2, r1. p1 ⊕ p2 ≍ r1 → ∀p3, s1. r1 ⊕ p3 ≍ s1 →
- ∀r3. p2 ⊕ p3 ≍ r3 → ∀s3. p1 ⊕ r3 ≍ s3 → s1 = s3.
- intros 4; elim H; clear H p2 r1;
- [ lapply linear nplus_inv_zero_1 to H2. destruct.
- lapply nplus_mono to H1, H3. destruct. autobatch
- | lapply linear nplus_inv_succ_1 to H3. decompose. destruct.
- lapply linear nplus_inv_succ_1 to H4. decompose. destruct.
- lapply linear nplus_inv_succ_2 to H5. decompose. destruct. autobatch
- ].
-qed.
-
-(* Corollaries of functional properties **************************************)
-
-theorem nplus_inj_2: ∀p, q1, r. p ⊕ q1 ≍ r → ∀q2. p ⊕ q2 ≍ r → q1 = q2.
- intros. autobatch.
-qed.
-
-(* Corollaries of nonoidal properties ***************************************)
-
-theorem nplus_comm_1: ∀p1, q, r1. p1 ⊕ q ≍ r1 → ∀p2, r2. p2 ⊕ q ≍ r2 →
- ∀x. p2 ⊕ r1 ≍ x → ∀y. p1 ⊕ r2 ≍ y → x = y.
- intros 4; elim H; clear H q r1;
- [ lapply linear nplus_inv_zero_2 to H1
- | lapply linear nplus_inv_succ_2 to H3.
- lapply linear nplus_inv_succ_2 to H4. decompose. destruct.
- lapply linear nplus_inv_succ_2 to H5. decompose
- ]; destruct; autobatch.
-qed.
-
-theorem nplus_comm_1_rew: ∀p1,q,r1. p1 ⊕ q ≍ r1 → ∀p2,r2. p2 ⊕ q ≍ r2 →
- ∀s. p1 ⊕ r2 ≍ s → p2 ⊕ r1 ≍ s.
- intros 4; elim H; clear H q r1;
- [ lapply linear nplus_inv_zero_2 to H1. destruct
- | lapply linear nplus_inv_succ_2 to H3. decompose. destruct.
- lapply linear nplus_inv_succ_2 to H4. decompose. destruct
- ]; autobatch.
-qed.
-
-(*
-theorem nplus_shift_succ_sx: \forall p,q,r.
- (p \oplus (succ q) \asymp r) \to (succ p) \oplus q \asymp r.
- intros.
- lapply linear nplus_inv_succ_2 to H as H0.
- decompose. destruct. auto new timeout=100.
-qed.
-
-theorem nplus_shift_succ_dx: \forall p,q,r.
- ((succ p) \oplus q \asymp r) \to p \oplus (succ q) \asymp r.
- intros.
- lapply linear nplus_inv_succ_1 to H as H0.
- decompose. destruct. auto new timeout=100.
-qed.
-
-theorem nplus_trans_1: \forall p,q1,r1. (p \oplus q1 \asymp r1) \to
- \forall q2,r2. (r1 \oplus q2 \asymp r2) \to
- \exists q. (q1 \oplus q2 \asymp q) \land p \oplus q \asymp r2.
- intros 2; elim q1; clear q1; intros;
- [ lapply linear nplus_inv_zero_2 to H as H0.
- destruct.
- | lapply linear nplus_inv_succ_2 to H1 as H0.
- decompose. destruct.
- lapply linear nplus_inv_succ_1 to H2 as H0.
- decompose. destruct.
- lapply linear H to H4, H3 as H0.
- decompose.
- ]; apply ex_intro; [| auto new timeout=100 || auto new timeout=100 ]. (**)
-qed.
-
-theorem nplus_trans_2: ∀p1,q,r1. p1 ⊕ q ≍ r1 → ∀p2,r2. p2 ⊕ r1 ≍ r2 →
- ∃p. p1 ⊕ p2 ≍ p ∧ p ⊕ q ≍ r2.
- intros 2; elim q; clear q; intros;
- [ lapply linear nplus_inv_zero_2 to H as H0.
- destruct
- | lapply linear nplus_inv_succ_2 to H1 as H0.
- decompose. destruct.
- lapply linear nplus_inv_succ_2 to H2 as H0.
- decompose. destruct.
- lapply linear H to H4, H3 as H0.
- decompose.
- ]; autobatch. apply ex_intro; [| auto new timeout=100 || auto new timeout=100 ]. (**)
-qed.
-*)