diff --git a/src/builtin/Nat.lean b/src/builtin/Nat.lean index f090586beb..e943b6d64a 100644 --- a/src/builtin/Nat.lean +++ b/src/builtin/Nat.lean @@ -21,10 +21,10 @@ definition ge (a b : Nat) := b ≤ a infix 50 >= : ge infix 50 ≥ : ge -definition lt (a b : Nat) := ¬ (a ≥ b) +definition lt (a b : Nat) := a + 1 ≤ b infix 50 < : lt -definition gt (a b : Nat) := ¬ (a ≤ b) +definition gt (a b : Nat) := b < a infix 50 > : gt definition id (a : Nat) := a @@ -37,10 +37,13 @@ axiom add_succr (a b : Nat) : a + (b + 1) = (a + b) + 1 axiom mul_zeror (a : Nat) : a * 0 = 0 axiom mul_succr (a b : Nat) : a * (b + 1) = a * b + a axiom le_def (a b : Nat) : a ≤ b = ∃ c, a + c = b -axiom induction {P : Nat → Bool} (a : Nat) (H1 : P 0) (H2 : ∀ (n : Nat) (iH : P n), P (n + 1)) : P a +axiom induction {P : Nat → Bool} (H1 : P 0) (H2 : ∀ (n : Nat) (iH : P n), P (n + 1)) : ∀ a, P a + +theorem induction_on {P : Nat → Bool} (a : Nat) (H1 : P 0) (H2 : ∀ (n : Nat) (iH : P n), P (n + 1)) : P a +:= induction H1 H2 a theorem pred_nz {a : Nat} : a ≠ 0 → ∃ b, b + 1 = a -:= induction a +:= induction_on a (λ H : 0 ≠ 0, false_elim (∃ b, b + 1 = 0) H) (λ (n : Nat) (iH : n ≠ 0 → ∃ b, b + 1 = n) (H : n + 1 ≠ 0), or_elim (em (n = 0)) @@ -56,14 +59,14 @@ theorem discriminate {B : Bool} {a : Nat} (H1: a = 0 → B) (H2 : ∀ n, a = n + H2 w (symm Hw)) theorem add_zerol (a : Nat) : 0 + a = a -:= induction a +:= induction_on a (have 0 + 0 = 0 : trivial) (λ (n : Nat) (iH : 0 + n = n), calc 0 + (n + 1) = (0 + n) + 1 : add_succr 0 n ... = n + 1 : { iH }) theorem add_succl (a b : Nat) : (a + 1) + b = (a + b) + 1 -:= induction b +:= induction_on b (calc (a + 1) + 0 = a + 1 : add_zeror (a + 1) ... = (a + 0) + 1 : { symm (add_zeror a) }) (λ (n : Nat) (iH : (a + 1) + n = (a + n) + 1), @@ -72,7 +75,7 @@ theorem add_succl (a b : Nat) : (a + 1) + b = (a + b) + 1 ... = (a + (n + 1)) + 1 : { have (a + n) + 1 = a + (n + 1) : symm (add_succr a n) }) theorem add_comm (a b : Nat) : a + b = b + a -:= induction b +:= induction_on b (calc a + 0 = a : add_zeror a ... = 0 + a : symm (add_zerol a)) (λ (n : Nat) (iH : a + n = n + a), @@ -81,7 +84,7 @@ theorem add_comm (a b : Nat) : a + b = b + a ... = (n + 1) + a : symm (add_succl n a)) theorem add_assoc (a b c : Nat) : a + (b + c) = (a + b) + c -:= induction a +:= induction_on a (calc 0 + (b + c) = b + c : add_zerol (b + c) ... = (0 + b) + c : { symm (add_zerol b) }) (λ (n : Nat) (iH : n + (b + c) = (n + b) + c), @@ -91,7 +94,7 @@ theorem add_assoc (a b c : Nat) : a + (b + c) = (a + b) + c ... = ((n + 1) + b) + c : { have (n + b) + 1 = (n + 1) + b : symm (add_succl n b) }) theorem mul_zerol (a : Nat) : 0 * a = 0 -:= induction a +:= induction_on a (have 0 * 0 = 0 : trivial) (λ (n : Nat) (iH : 0 * n = 0), calc 0 * (n + 1) = (0 * n) + 0 : mul_succr 0 n @@ -99,7 +102,7 @@ theorem mul_zerol (a : Nat) : 0 * a = 0 ... = 0 : trivial) theorem mul_succl (a b : Nat) : (a + 1) * b = a * b + b -:= induction b +:= induction_on b (calc (a + 1) * 0 = 0 : mul_zeror (a + 1) ... = a * 0 : symm (mul_zeror a) ... = a * 0 + 0 : symm (add_zeror (a * 0))) @@ -114,21 +117,21 @@ theorem mul_succl (a b : Nat) : (a + 1) * b = a * b + b ... = a * (n + 1) + (n + 1) : symm (add_assoc (a * (n + 1)) n 1)) theorem mul_onel (a : Nat) : 1 * a = a -:= induction a +:= induction_on a (have 1 * 0 = 0 : trivial) (λ (n : Nat) (iH : 1 * n = n), calc 1 * (n + 1) = 1 * n + 1 : mul_succr 1 n ... = n + 1 : { iH }) theorem mul_oner (a : Nat) : a * 1 = a -:= induction a +:= induction_on a (have 0 * 1 = 0 : trivial) (λ (n : Nat) (iH : n * 1 = n), calc (n + 1) * 1 = n * 1 + 1 : mul_succl n 1 ... = n + 1 : { iH }) theorem mul_comm (a b : Nat) : a * b = b * a -:= induction b +:= induction_on b (calc a * 0 = 0 : mul_zeror a ... = 0 * a : symm (mul_zerol a)) (λ (n : Nat) (iH : a * n = n * a), @@ -137,7 +140,7 @@ theorem mul_comm (a b : Nat) : a * b = b * a ... = (n + 1) * a : symm (mul_succl n a)) theorem distributer (a b c : Nat) : a * (b + c) = a * b + a * c -:= induction a +:= induction_on a (calc 0 * (b + c) = 0 : mul_zerol (b + c) ... = 0 + 0 : trivial ... = 0 * b + 0 : { symm (mul_zerol b) } @@ -160,7 +163,7 @@ theorem distributel (a b c : Nat) : (a + b) * c = a * c + b * c ... = a * c + b * c : { mul_comm c b } theorem mul_assoc (a b c : Nat) : a * (b * c) = a * b * c -:= induction a +:= induction_on a (calc 0 * (b * c) = 0 : mul_zerol (b * c) ... = 0 * c : symm (mul_zerol c) ... = (0 * b) * c : { symm (mul_zerol b) }) @@ -170,8 +173,8 @@ theorem mul_assoc (a b c : Nat) : a * (b * c) = a * b * c ... = (n * b + b) * c : symm (distributel (n * b) b c) ... = (n + 1) * b * c : { symm (mul_succl n b) }) -theorem add_inj {a b c : Nat} : a + b = a + c → b = c -:= induction a +theorem add_injr {a b c : Nat} : a + b = a + c → b = c +:= induction_on a (λ H : 0 + b = 0 + c, calc b = 0 + b : symm (add_zerol b) ... = 0 + c : H @@ -188,6 +191,11 @@ theorem add_inj {a b c : Nat} : a + b = a + c → b = c L2 : n + b = n + c := succ_inj L1 in iH L2) +theorem add_injl {a b c : Nat} (H : a + b = c + b) : a = c +:= add_injr (calc b + a = a + b : add_comm _ _ + ... = c + b : H + ... = b + c : add_comm _ _) + theorem add_eqz {a b : Nat} (H : a + b = 0) : a = 0 := discriminate (λ H1 : a = 0, H1) @@ -228,7 +236,7 @@ theorem le_antisym {a b : Nat} (H1 : a ≤ b) (H2 : b ≤ a) : a = b := obtain (w1 : Nat) (Hw1 : a + w1 = b), from (le_elim H1), obtain (w2 : Nat) (Hw2 : b + w2 = a), from (le_elim H2), let L1 : w1 + w2 = 0 - := add_inj (calc a + (w1 + w2) = a + w1 + w2 : { add_assoc a w1 w2 } + := add_injr (calc a + (w1 + w2) = a + w1 + w2 : { add_assoc a w1 w2 } ... = b + w2 : { Hw1 } ... = a : Hw2 ... = a + 0 : symm (add_zeror a)), @@ -237,6 +245,104 @@ theorem le_antisym {a b : Nat} (H1 : a ≤ b) (H2 : b ≤ a) : a = b ... = a + w1 : { symm L2 } ... = b : Hw1 +theorem not_lt_0 (a : Nat) : ¬ a < 0 +:= not_intro (λ H : a + 1 ≤ 0, + obtain (w : Nat) (Hw1 : a + 1 + w = 0), from (le_elim H), + absurd + (calc a + w + 1 = a + (w + 1) : symm (add_assoc _ _ _) + ... = a + (1 + w) : { add_comm _ _ } + ... = a + 1 + w : add_assoc _ _ _ + ... = 0 : Hw1) + (succ_nz (a + w))) + +theorem lt_intro {a b c : Nat} (H : a + 1 + c = b) : a < b +:= le_intro H + +theorem lt_elim {a b : Nat} (H : a < b) : ∃ x, a + 1 + x = b +:= le_elim H + +theorem lt_le {a b : Nat} (H : a < b) : a ≤ b +:= obtain (w : Nat) (Hw : a + 1 + w = b), from (le_elim H), + le_intro (calc a + (1 + w) = a + 1 + w : add_assoc _ _ _ + ... = b : Hw) + +theorem lt_ne {a b : Nat} (H : a < b) : a ≠ b +:= not_intro (λ H1 : a = b, + obtain (w : Nat) (Hw : a + 1 + w = b), from (lt_elim H), + absurd (calc w + 1 = 1 + w : add_comm _ _ + ... = 0 : + add_injr (calc b + (1 + w) = b + 1 + w : add_assoc b 1 w + ... = a + 1 + w : { symm H1 } + ... = b : Hw + ... = b + 0 : symm (add_zeror b))) + (succ_nz w)) + +theorem lt_nrefl (a : Nat) : ¬ a < a +:= not_intro (λ H : a < a, + absurd (refl a) (lt_ne H)) + +theorem lt_trans {a b c : Nat} (H1 : a < b) (H2 : b < c) : a < c +:= obtain (w1 : Nat) (Hw1 : a + 1 + w1 = b), from (lt_elim H1), + obtain (w2 : Nat) (Hw2 : b + 1 + w2 = c), from (lt_elim H2), + lt_intro (calc a + 1 + (w1 + 1 + w2) = a + 1 + (w1 + (1 + w2)) : { symm (add_assoc w1 1 w2) } + ... = (a + 1 + w1) + (1 + w2) : add_assoc _ _ _ + ... = b + (1 + w2) : { Hw1 } + ... = b + 1 + w2 : add_assoc _ _ _ + ... = c : Hw2) + +theorem lt_le_trans {a b c : Nat} (H1 : a < b) (H2 : b ≤ c) : a < c +:= obtain (w1 : Nat) (Hw1 : a + 1 + w1 = b), from (lt_elim H1), + obtain (w2 : Nat) (Hw2 : b + w2 = c), from (le_elim H2), + lt_intro (calc a + 1 + (w1 + w2) = a + 1 + w1 + w2 : add_assoc _ _ _ + ... = b + w2 : { Hw1 } + ... = c : Hw2) + +theorem le_lt_trans {a b c : Nat} (H1 : a ≤ b) (H2 : b < c) : a < c +:= obtain (w1 : Nat) (Hw1 : a + w1 = b), from (le_elim H1), + obtain (w2 : Nat) (Hw2 : b + 1 + w2 = c), from (lt_elim H2), + lt_intro (calc a + 1 + (w1 + w2) = a + 1 + w1 + w2 : add_assoc _ _ _ + ... = a + (1 + w1) + w2 : { symm (add_assoc a 1 w1) } + ... = a + (w1 + 1) + w2 : { add_comm 1 w1 } + ... = a + w1 + 1 + w2 : { add_assoc a w1 1 } + ... = b + 1 + w2 : { Hw1 } + ... = c : Hw2) + +theorem ne_lt_succ {a b : Nat} (H1 : a ≠ b) (H2 : a < b + 1) : a < b +:= obtain (w : Nat) (Hw : a + 1 + w = b + 1), from (lt_elim H2), + let L : a + w = b := add_injl (calc a + w + 1 = a + (w + 1) : symm (add_assoc _ _ _) + ... = a + (1 + w) : { add_comm _ _ } + ... = a + 1 + w : add_assoc _ _ _ + ... = b + 1 : Hw) + in discriminate (λ Hz : w = 0, absurd_elim (a < b) (calc a = a + 0 : symm (add_zeror _) + ... = a + w : { symm Hz } + ... = b : L) + H1) + (λ (p : Nat) (Hp : w = p + 1), lt_intro (calc a + 1 + p = a + (1 + p) : symm (add_assoc _ _ _) + ... = a + (p + 1) : { add_comm _ _ } + ... = a + w : { symm Hp } + ... = b : L)) + +theorem strong_induction {P : Nat → Bool} (H : ∀ n, (∀ m, m < n → P m) → P n) : ∀ a, P a +:= λ a, + let stronger : P a ∧ ∀ m, m < a → P m := + -- we prove a stronger result by regular induction on a + induction_on a + (have P 0 ∧ ∀ m, m < 0 → P m : + let c2 : ∀ m, m < 0 → P m := λ (m : Nat) (Hlt : m < 0), absurd_elim (P m) Hlt (not_lt_0 m), + c1 : P 0 := H 0 c2 + in and_intro c1 c2) + (λ (n : Nat) (iH : P n ∧ ∀ m, m < n → P m), + have P (n + 1) ∧ ∀ m, m < n + 1 → P m : + let iH1 : P n := and_eliml iH, + iH2 : ∀ m, m < n → P m := and_elimr iH, + c2 : ∀ m, m < n + 1 → P m := λ (m : Nat) (Hlt : m < n + 1), + or_elim (em (m = n)) + (λ Heq : m = n, subst iH1 (symm Heq)) + (λ Hne : m ≠ n, iH2 m (ne_lt_succ Hne Hlt)), + c1 : P (n + 1) := H (n + 1) c2 + in and_intro c1 c2) + in and_eliml stronger + set_opaque add true set_opaque mul true set_opaque le true diff --git a/src/builtin/kernel.lean b/src/builtin/kernel.lean index 1b3e0c1770..3db5e8a5ba 100644 --- a/src/builtin/kernel.lean +++ b/src/builtin/kernel.lean @@ -64,6 +64,10 @@ axiom allext {A : TypeU} {B C : A → TypeU} (H : ∀ x : A, B x == C x) : (∀ theorem substp {A : TypeU} {a b : A} (P : A → Bool) (H1 : P a) (H2 : a == b) : P b := subst H1 H2 +-- We will mark not as opaque later +theorem not_intro {a : Bool} (H : a → false) : ¬ a +:= H + theorem eta {A : TypeU} {B : A → TypeU} (f : ∀ x : A, B x) : (λ x : A, f x) == f := funext (λ x : A, refl (f x)) diff --git a/src/builtin/obj/Nat.olean b/src/builtin/obj/Nat.olean index afbe1a8d74..aa07bb8c14 100644 Binary files a/src/builtin/obj/Nat.olean and b/src/builtin/obj/Nat.olean differ diff --git a/src/builtin/obj/kernel.olean b/src/builtin/obj/kernel.olean index c6bc65842c..52812acc8f 100644 Binary files a/src/builtin/obj/kernel.olean and b/src/builtin/obj/kernel.olean differ diff --git a/src/kernel/kernel_decls.cpp b/src/kernel/kernel_decls.cpp index 27be7341f6..4ad3a76e6d 100644 --- a/src/kernel/kernel_decls.cpp +++ b/src/kernel/kernel_decls.cpp @@ -22,6 +22,7 @@ MK_CONSTANT(subst_fn, name("subst")); MK_CONSTANT(funext_fn, name("funext")); MK_CONSTANT(allext_fn, name("allext")); MK_CONSTANT(substp_fn, name("substp")); +MK_CONSTANT(not_intro_fn, name("not_intro")); MK_CONSTANT(eta_fn, name("eta")); MK_CONSTANT(trivial, name("trivial")); MK_CONSTANT(absurd_fn, name("absurd")); diff --git a/src/kernel/kernel_decls.h b/src/kernel/kernel_decls.h index aea60526a1..6d9b63d719 100644 --- a/src/kernel/kernel_decls.h +++ b/src/kernel/kernel_decls.h @@ -58,6 +58,9 @@ inline expr mk_allext_th(expr const & e1, expr const & e2, expr const & e3, expr expr mk_substp_fn(); bool is_substp_fn(expr const & e); inline expr mk_substp_th(expr const & e1, expr const & e2, expr const & e3, expr const & e4, expr const & e5, expr const & e6) { return mk_app({mk_substp_fn(), e1, e2, e3, e4, e5, e6}); } +expr mk_not_intro_fn(); +bool is_not_intro_fn(expr const & e); +inline expr mk_not_intro_th(expr const & e1, expr const & e2) { return mk_app({mk_not_intro_fn(), e1, e2}); } expr mk_eta_fn(); bool is_eta_fn(expr const & e); inline expr mk_eta_th(expr const & e1, expr const & e2, expr const & e3) { return mk_app({mk_eta_fn(), e1, e2, e3}); } diff --git a/src/library/arith/Nat_decls.cpp b/src/library/arith/Nat_decls.cpp index 4eff54b543..bce59a39f9 100644 --- a/src/library/arith/Nat_decls.cpp +++ b/src/library/arith/Nat_decls.cpp @@ -19,6 +19,7 @@ MK_CONSTANT(Nat_mul_zeror_fn, name({"Nat", "mul_zeror"})); MK_CONSTANT(Nat_mul_succr_fn, name({"Nat", "mul_succr"})); MK_CONSTANT(Nat_le_def_fn, name({"Nat", "le_def"})); MK_CONSTANT(Nat_induction_fn, name({"Nat", "induction"})); +MK_CONSTANT(Nat_induction_on_fn, name({"Nat", "induction_on"})); MK_CONSTANT(Nat_pred_nz_fn, name({"Nat", "pred_nz"})); MK_CONSTANT(Nat_discriminate_fn, name({"Nat", "discriminate"})); MK_CONSTANT(Nat_add_zerol_fn, name({"Nat", "add_zerol"})); @@ -33,7 +34,8 @@ MK_CONSTANT(Nat_mul_comm_fn, name({"Nat", "mul_comm"})); MK_CONSTANT(Nat_distributer_fn, name({"Nat", "distributer"})); MK_CONSTANT(Nat_distributel_fn, name({"Nat", "distributel"})); MK_CONSTANT(Nat_mul_assoc_fn, name({"Nat", "mul_assoc"})); -MK_CONSTANT(Nat_add_inj_fn, name({"Nat", "add_inj"})); +MK_CONSTANT(Nat_add_injr_fn, name({"Nat", "add_injr"})); +MK_CONSTANT(Nat_add_injl_fn, name({"Nat", "add_injl"})); MK_CONSTANT(Nat_add_eqz_fn, name({"Nat", "add_eqz"})); MK_CONSTANT(Nat_le_intro_fn, name({"Nat", "le_intro"})); MK_CONSTANT(Nat_le_elim_fn, name({"Nat", "le_elim"})); @@ -42,4 +44,15 @@ MK_CONSTANT(Nat_le_zero_fn, name({"Nat", "le_zero"})); MK_CONSTANT(Nat_le_trans_fn, name({"Nat", "le_trans"})); MK_CONSTANT(Nat_le_add_fn, name({"Nat", "le_add"})); MK_CONSTANT(Nat_le_antisym_fn, name({"Nat", "le_antisym"})); +MK_CONSTANT(Nat_not_lt_0_fn, name({"Nat", "not_lt_0"})); +MK_CONSTANT(Nat_lt_intro_fn, name({"Nat", "lt_intro"})); +MK_CONSTANT(Nat_lt_elim_fn, name({"Nat", "lt_elim"})); +MK_CONSTANT(Nat_lt_le_fn, name({"Nat", "lt_le"})); +MK_CONSTANT(Nat_lt_ne_fn, name({"Nat", "lt_ne"})); +MK_CONSTANT(Nat_lt_nrefl_fn, name({"Nat", "lt_nrefl"})); +MK_CONSTANT(Nat_lt_trans_fn, name({"Nat", "lt_trans"})); +MK_CONSTANT(Nat_lt_le_trans_fn, name({"Nat", "lt_le_trans"})); +MK_CONSTANT(Nat_le_lt_trans_fn, name({"Nat", "le_lt_trans"})); +MK_CONSTANT(Nat_ne_lt_succ_fn, name({"Nat", "ne_lt_succ"})); +MK_CONSTANT(Nat_strong_induction_fn, name({"Nat", "strong_induction"})); } diff --git a/src/library/arith/Nat_decls.h b/src/library/arith/Nat_decls.h index fa0830b876..d7ed8f6d90 100644 --- a/src/library/arith/Nat_decls.h +++ b/src/library/arith/Nat_decls.h @@ -47,6 +47,9 @@ inline expr mk_Nat_le_def_th(expr const & e1, expr const & e2) { return mk_app({ expr mk_Nat_induction_fn(); bool is_Nat_induction_fn(expr const & e); inline expr mk_Nat_induction_th(expr const & e1, expr const & e2, expr const & e3, expr const & e4) { return mk_app({mk_Nat_induction_fn(), e1, e2, e3, e4}); } +expr mk_Nat_induction_on_fn(); +bool is_Nat_induction_on_fn(expr const & e); +inline expr mk_Nat_induction_on_th(expr const & e1, expr const & e2, expr const & e3, expr const & e4) { return mk_app({mk_Nat_induction_on_fn(), e1, e2, e3, e4}); } expr mk_Nat_pred_nz_fn(); bool is_Nat_pred_nz_fn(expr const & e); inline expr mk_Nat_pred_nz_th(expr const & e1, expr const & e2) { return mk_app({mk_Nat_pred_nz_fn(), e1, e2}); } @@ -89,9 +92,12 @@ inline expr mk_Nat_distributel_th(expr const & e1, expr const & e2, expr const & expr mk_Nat_mul_assoc_fn(); bool is_Nat_mul_assoc_fn(expr const & e); inline expr mk_Nat_mul_assoc_th(expr const & e1, expr const & e2, expr const & e3) { return mk_app({mk_Nat_mul_assoc_fn(), e1, e2, e3}); } -expr mk_Nat_add_inj_fn(); -bool is_Nat_add_inj_fn(expr const & e); -inline expr mk_Nat_add_inj_th(expr const & e1, expr const & e2, expr const & e3, expr const & e4) { return mk_app({mk_Nat_add_inj_fn(), e1, e2, e3, e4}); } +expr mk_Nat_add_injr_fn(); +bool is_Nat_add_injr_fn(expr const & e); +inline expr mk_Nat_add_injr_th(expr const & e1, expr const & e2, expr const & e3, expr const & e4) { return mk_app({mk_Nat_add_injr_fn(), e1, e2, e3, e4}); } +expr mk_Nat_add_injl_fn(); +bool is_Nat_add_injl_fn(expr const & e); +inline expr mk_Nat_add_injl_th(expr const & e1, expr const & e2, expr const & e3, expr const & e4) { return mk_app({mk_Nat_add_injl_fn(), e1, e2, e3, e4}); } expr mk_Nat_add_eqz_fn(); bool is_Nat_add_eqz_fn(expr const & e); inline expr mk_Nat_add_eqz_th(expr const & e1, expr const & e2, expr const & e3) { return mk_app({mk_Nat_add_eqz_fn(), e1, e2, e3}); } @@ -116,4 +122,37 @@ inline expr mk_Nat_le_add_th(expr const & e1, expr const & e2, expr const & e3, expr mk_Nat_le_antisym_fn(); bool is_Nat_le_antisym_fn(expr const & e); inline expr mk_Nat_le_antisym_th(expr const & e1, expr const & e2, expr const & e3, expr const & e4) { return mk_app({mk_Nat_le_antisym_fn(), e1, e2, e3, e4}); } +expr mk_Nat_not_lt_0_fn(); +bool is_Nat_not_lt_0_fn(expr const & e); +inline expr mk_Nat_not_lt_0_th(expr const & e1) { return mk_app({mk_Nat_not_lt_0_fn(), e1}); } +expr mk_Nat_lt_intro_fn(); +bool is_Nat_lt_intro_fn(expr const & e); +inline expr mk_Nat_lt_intro_th(expr const & e1, expr const & e2, expr const & e3, expr const & e4) { return mk_app({mk_Nat_lt_intro_fn(), e1, e2, e3, e4}); } +expr mk_Nat_lt_elim_fn(); +bool is_Nat_lt_elim_fn(expr const & e); +inline expr mk_Nat_lt_elim_th(expr const & e1, expr const & e2, expr const & e3) { return mk_app({mk_Nat_lt_elim_fn(), e1, e2, e3}); } +expr mk_Nat_lt_le_fn(); +bool is_Nat_lt_le_fn(expr const & e); +inline expr mk_Nat_lt_le_th(expr const & e1, expr const & e2, expr const & e3) { return mk_app({mk_Nat_lt_le_fn(), e1, e2, e3}); } +expr mk_Nat_lt_ne_fn(); +bool is_Nat_lt_ne_fn(expr const & e); +inline expr mk_Nat_lt_ne_th(expr const & e1, expr const & e2, expr const & e3) { return mk_app({mk_Nat_lt_ne_fn(), e1, e2, e3}); } +expr mk_Nat_lt_nrefl_fn(); +bool is_Nat_lt_nrefl_fn(expr const & e); +inline expr mk_Nat_lt_nrefl_th(expr const & e1) { return mk_app({mk_Nat_lt_nrefl_fn(), e1}); } +expr mk_Nat_lt_trans_fn(); +bool is_Nat_lt_trans_fn(expr const & e); +inline expr mk_Nat_lt_trans_th(expr const & e1, expr const & e2, expr const & e3, expr const & e4, expr const & e5) { return mk_app({mk_Nat_lt_trans_fn(), e1, e2, e3, e4, e5}); } +expr mk_Nat_lt_le_trans_fn(); +bool is_Nat_lt_le_trans_fn(expr const & e); +inline expr mk_Nat_lt_le_trans_th(expr const & e1, expr const & e2, expr const & e3, expr const & e4, expr const & e5) { return mk_app({mk_Nat_lt_le_trans_fn(), e1, e2, e3, e4, e5}); } +expr mk_Nat_le_lt_trans_fn(); +bool is_Nat_le_lt_trans_fn(expr const & e); +inline expr mk_Nat_le_lt_trans_th(expr const & e1, expr const & e2, expr const & e3, expr const & e4, expr const & e5) { return mk_app({mk_Nat_le_lt_trans_fn(), e1, e2, e3, e4, e5}); } +expr mk_Nat_ne_lt_succ_fn(); +bool is_Nat_ne_lt_succ_fn(expr const & e); +inline expr mk_Nat_ne_lt_succ_th(expr const & e1, expr const & e2, expr const & e3, expr const & e4) { return mk_app({mk_Nat_ne_lt_succ_fn(), e1, e2, e3, e4}); } +expr mk_Nat_strong_induction_fn(); +bool is_Nat_strong_induction_fn(expr const & e); +inline expr mk_Nat_strong_induction_th(expr const & e1, expr const & e2, expr const & e3) { return mk_app({mk_Nat_strong_induction_fn(), e1, e2, e3}); } }