lean2/src/library/basic_thms.h

/*
Copyright (c) 2013 Microsoft Corporation. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.

Author: Leonardo de Moura
*/
#pragma once
#include "kernel/builtin.h"

namespace lean {
expr mk_trivial();
/** \brief (Theorem) Trivial : True */
#define Trivial mk_trivial()

expr mk_true_ne_false();
/** \brief (Theorem) TrueNeFalse : Not(True = False) */
#define TrueNeFalse mk_true_ne_false();

expr mk_em_fn();
/** \brief (Theorem) a : Bool |- EM(a) : Or(a, Not(a)) */
inline expr EM(expr const & a) { return mk_app(mk_em_fn(), a); }

expr mk_false_elim_fn();
/** \brief (Theorem) a : Bool, H : False |- FalseElim(a, H) : a */
inline expr FalseElim(expr const & a, expr const & H) { return mk_app(mk_false_elim_fn(), a, H); }

expr mk_absurd_fn();
/** \brief (Theorem) {a : Bool}, H1 : a, H2 : Not(a) |- Absurd(a, H1, H2) : False */
inline expr Absurd(expr const & a, expr const & H1, expr const & H2) { return mk_app(mk_absurd_fn(), a, H1, H2); }

expr mk_double_neg_fn();
/** \brief (Theorem) a : Bool |- DoubleNeg(a) : Neg(Neg(a)) = a */
inline expr DoubleNeg(expr const & a) { return mk_app(mk_double_neg_fn(), a); }

expr mk_double_neg_elim_fn();
/** \brief (Theorem) {a : Bool}, {P : Bool -> Bool}, H : P (Not (Not a)) |- DoubleNegElim(a, P, H) : P a */
inline expr DoubleNegElim(expr const & a, expr const & P, expr const & H) { return mk_app(mk_double_neg_elim_fn(), a, P, H); }

expr mk_mt_fn();
/** \brief (Theorem) {a b : Bool}, H1 : a => b, H2 : Not(b) |- MT(a, b, H1, H2) : Not(a) */
inline expr MT(expr const & a, expr const & b, expr const & H1, expr const & H2) { return mk_app(mk_mt_fn(), a, b, H1, H2); }

expr mk_contrapos_fn();
/** \brief (Theorem) {a b : Bool}, H : a => b |- Contrapos(a, b, H): Neg(b) => Neg(a) */
inline expr Contrapos(expr const & a, expr const & b, expr const & H) { return mk_app(mk_contrapos_fn(), a, b, H); }

expr mk_false_imp_any_fn();
/** \brief (Theorem) a : Bool, H : False |- a */
inline expr FalseImpAny(expr const & a, expr const & H) { return mk_app(mk_false_imp_any_fn(), a, H); }

expr mk_eq_mp_fn();
/** \brief (Theorem) {a b : Bool}, H1 : a = b, H2 : a |- EqMP(a, b, H1, H2) : b */
inline expr EqMP(expr const & a, expr const & b, expr const & H1, expr const & H2) { return mk_app(mk_eq_mp_fn(), a, b, H1, H2); }

expr mk_not_imp1_fn();
/** \brief (Theorem) {a b : Bool}, H : Not(Implies(a, b)) |- NotImp1(a, b, H) : a */
inline expr NotImp1(expr const & a, expr const & b, expr const & H) { return mk_app(mk_not_imp1_fn(), a, b, H); }

expr mk_not_imp2_fn();
/** \brief (Theorem) {a b : Bool}, H : Not(Implies(a, b)) |- NotImp2(a, b, H) : Not(b) */
inline expr NotImp2(expr const & a, expr const & b, expr const & H) { return mk_app(mk_not_imp2_fn(), a, b, H); }

expr mk_conj_fn();
/** \brief (Theorem) {a b : Bool}, H1 : a, H2 : b |- Conj(a, b, H1, H2) : And(a, b) */
inline expr Conj(expr const & a, expr const & b, expr const & H1, expr const & H2) { return mk_app(mk_conj_fn(), a, b, H1, H2); }

expr mk_conjunct1_fn();
/** \brief (Theorem) {a b : Bool}, H : And(a, b) |- Conjunct1(a, b, H) : a */
inline expr Conjunct1(expr const & a, expr const & b, expr const & H) { return mk_app(mk_conjunct1_fn(), a, b, H); }

expr mk_conjunct2_fn();
/** \brief (Theorem) {a b : Bool}, H : And(a, b) |- Conjunct2(a, b, H) : b */
inline expr Conjunct2(expr const & a, expr const & b, expr const & H) { return mk_app(mk_conjunct2_fn(), a, b, H); }

expr mk_disj1_fn();
/** \brief (Theorem) a b : Bool, H : a |- Disj1(a, b, H) : Or(a, b) */
inline expr Disj1(expr const & a, expr const & b, expr const & H) { return mk_app(mk_disj1_fn(), a, b, H); }

expr mk_disj2_fn();
/** \brief (Theorem) {b} a : Bool, H : b |- Disj2(a, b, H) : Or(a, b) */
inline expr Disj2(expr const & b, expr const & a, expr const & H) { return mk_app(mk_disj2_fn(), b, a, H); }

expr mk_disj_cases_fn();
/** \brief (Theorem) {a b c : Bool}, H1 : Or(a,b), H2 : a -> c, H3 : b -> c |- DisjCases(a, b, c, H1, H2, H3) : c */
inline expr DisjCases(expr const & a, expr const & b, expr const & c, expr const & H1, expr const & H2, expr const & H3) { return mk_app({mk_disj_cases_fn(), a, b, c, H1, H2, H3}); }

expr mk_symm_fn();
/** \brief (Theorem) {A : Type u}, {a b : A}, H : a = b |- Symm(A, a, b, H) : b = a */
inline expr Symm(expr const & A, expr const & a, expr const & b, expr const & H) { return mk_app(mk_symm_fn(), A, a, b, H); }

expr mk_trans_fn();
/** \brief (Theorem) {A : Type u}, {a b c : A}, H1 : a = b, H2 : b = c |- Trans(A, a, b, c, H1, H2) : a = c */
inline expr Trans(expr const & A, expr const & a, expr const & b, expr const & c, expr const & H1, expr const & H2) { return mk_app({mk_trans_fn(), A, a, b, c, H1, H2}); }

expr mk_trans_ext_fn();
/** \brief (Theorem) {A : Type u}, {B : Type u}, {a : A}, {b c : B}, H1 : a = b, H2 : b = c |- TransExt(A, B, a, b, c, H1, H2) : a = c */
inline expr TransExt(expr const & A, expr const & B, expr const & a, expr const & b, expr const & c, expr const & H1, expr const & H2) { return mk_app({mk_trans_ext_fn(), A, B, a, b, c, H1, H2}); }

expr mk_eqt_elim_fn();
/** \brief (Theorem) {a : Bool}, H : a = True |- EqTElim(a, H) : a */
inline expr EqTElim(expr const & a, expr const & H) { return mk_app(mk_eqt_elim_fn(), a, H); }

expr mk_eqt_intro_fn();
/** \brief (Theorem) {a : Bool}, H : a |- EqTIntro(a, H) : a = True */
inline expr EqTIntro(expr const & a, expr const & H) { return mk_app(mk_eqt_intro_fn(), a, H); }

expr mk_congr1_fn();
/** \brief (Theorem) {A : Type u}, {B : A -> Type u}, {f g : (Pi x : A, B x)}, a : A, H : f = g |- Congr2(A, B, f, g, a, H) : f a = g a */
inline expr Congr1(expr const & A, expr const & B, expr const & f, expr const & g, expr const & a, expr const & H) { return mk_app({mk_congr1_fn(), A, B, f, g, a, H}); }

expr mk_congr2_fn();
/** \brief (Theorem) {A : Type u}, {B : A -> Type u}, {a b : A}, f : (Pi x : A, B x), H : a = b |- Congr1(A, B, f, a, b, H) : f a = f b */
inline expr Congr2(expr const & A, expr const & B, expr const & a, expr const & b, expr const & f, expr const & H) { return mk_app({mk_congr2_fn(), A, B, a, b, f, H}); }

expr mk_congr_fn();
/** \brief (Theorem) {A : Type u}, {B : A -> Type u}, {f g : (Pi x : A, B x)}, {a b : A}, H1 : f = g, H2 : a = b |- Congr(A, B, f, g, a, b, H1, H2) : f a = g b */
inline expr Congr(expr const & A, expr const & B, expr const & f, expr const & g, expr const & a, expr const & b, expr const & H1, expr const & H2) { return mk_app({mk_congr_fn(), A, B, f, g, a, b, H1, H2}); }

expr mk_forall_elim_fn();
// \brief (Theorem) {A : Type u}, {P : A -> Bool}, H : (Forall A P), a : A |- Forallelim(A, P, H, a) : P a
inline expr ForallElim(expr const & A, expr const & P, expr const & H, expr const & a) { return mk_app(mk_forall_elim_fn(), A, P, H, a); }

/** \brief Add basic theorems to Environment */
void import_basic_thms(environment & env);

#if 0
expr mk_ext_fn();
bool is_ext_fn(expr const & e);
expr mk_foralli_fn();
bool is_foralli_fn(expr const & e);
expr mk_domain_inj_fn();
bool is_domain_inj_fn(expr const & e);
expr mk_range_inj_fn();
bool is_range_inj_fn(expr const & e);
#endif
}
Refactor theorems. Add new theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 08:16:37 +00:00			`/*`
			`Copyright (c) 2013 Microsoft Corporation. All rights reserved.`
			`Released under Apache 2.0 license as described in the file LICENSE.`

			`Author: Leonardo de Moura`
			`*/`
			`#pragma once`
Use fullpath in #include directives. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-09-13 03:04:10 +00:00			`#include "kernel/builtin.h"`
Refactor theorems. Add new theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 08:16:37 +00:00
			`namespace lean {`
Rename Truth to Trivial, and delete Trivial macro Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-08 04:16:04 +00:00			`expr mk_trivial();`
			`/** \brief (Theorem) Trivial : True */`
			`#define Trivial mk_trivial()`
Refactor theorems. Add new theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 08:16:37 +00:00
Add more theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 18:23:04 +00:00			`expr mk_true_ne_false();`
			`/** \brief (Theorem) TrueNeFalse : Not(True = False) */`
			`#define TrueNeFalse mk_true_ne_false();`

			`expr mk_em_fn();`
			`/** \brief (Theorem) a : Bool \|- EM(a) : Or(a, Not(a)) */`
			`inline expr EM(expr const & a) { return mk_app(mk_em_fn(), a); }`
Refactor theorems. Add new theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 08:16:37 +00:00
			`expr mk_false_elim_fn();`
			`/** \brief (Theorem) a : Bool, H : False \|- FalseElim(a, H) : a */`
			`inline expr FalseElim(expr const & a, expr const & H) { return mk_app(mk_false_elim_fn(), a, H); }`

Add more theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 18:23:04 +00:00			`expr mk_absurd_fn();`
Mark 'implicit' parameters, and move them to the beginning Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-08 04:47:58 +00:00			`/** \brief (Theorem) {a : Bool}, H1 : a, H2 : Not(a) \|- Absurd(a, H1, H2) : False */`
Add more theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 18:23:04 +00:00			`inline expr Absurd(expr const & a, expr const & H1, expr const & H2) { return mk_app(mk_absurd_fn(), a, H1, H2); }`

Refactor theorems. Add new theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 08:16:37 +00:00			`expr mk_double_neg_fn();`
			`/** \brief (Theorem) a : Bool \|- DoubleNeg(a) : Neg(Neg(a)) = a */`
			`inline expr DoubleNeg(expr const & a) { return mk_app(mk_double_neg_fn(), a); }`

Add more theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 18:23:04 +00:00			`expr mk_double_neg_elim_fn();`
Mark 'implicit' parameters, and move them to the beginning Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-08 04:47:58 +00:00			`/** \brief (Theorem) {a : Bool}, {P : Bool -> Bool}, H : P (Not (Not a)) \|- DoubleNegElim(a, P, H) : P a */`
Add more theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 18:23:04 +00:00			`inline expr DoubleNegElim(expr const & a, expr const & P, expr const & H) { return mk_app(mk_double_neg_elim_fn(), a, P, H); }`

Refactor theorems. Add new theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 08:16:37 +00:00			`expr mk_mt_fn();`
Mark 'implicit' parameters, and move them to the beginning Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-08 04:47:58 +00:00			`/** \brief (Theorem) {a b : Bool}, H1 : a => b, H2 : Not(b) \|- MT(a, b, H1, H2) : Not(a) */`
Refactor theorems. Add new theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 08:16:37 +00:00			`inline expr MT(expr const & a, expr const & b, expr const & H1, expr const & H2) { return mk_app(mk_mt_fn(), a, b, H1, H2); }`

			`expr mk_contrapos_fn();`
Mark 'implicit' parameters, and move them to the beginning Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-08 04:47:58 +00:00			`/** \brief (Theorem) {a b : Bool}, H : a => b \|- Contrapos(a, b, H): Neg(b) => Neg(a) */`
Refactor theorems. Add new theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 08:16:37 +00:00			`inline expr Contrapos(expr const & a, expr const & b, expr const & H) { return mk_app(mk_contrapos_fn(), a, b, H); }`

Add more theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 18:23:04 +00:00			`expr mk_false_imp_any_fn();`
			`/** \brief (Theorem) a : Bool, H : False \|- a */`
			`inline expr FalseImpAny(expr const & a, expr const & H) { return mk_app(mk_false_imp_any_fn(), a, H); }`

			`expr mk_eq_mp_fn();`
Mark 'implicit' parameters, and move them to the beginning Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-08 04:47:58 +00:00			`/** \brief (Theorem) {a b : Bool}, H1 : a = b, H2 : a \|- EqMP(a, b, H1, H2) : b */`
Add more theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 18:23:04 +00:00			`inline expr EqMP(expr const & a, expr const & b, expr const & H1, expr const & H2) { return mk_app(mk_eq_mp_fn(), a, b, H1, H2); }`

			`expr mk_not_imp1_fn();`
Mark 'implicit' parameters, and move them to the beginning Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-08 04:47:58 +00:00			`/** \brief (Theorem) {a b : Bool}, H : Not(Implies(a, b)) \|- NotImp1(a, b, H) : a */`
Add more theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 18:23:04 +00:00			`inline expr NotImp1(expr const & a, expr const & b, expr const & H) { return mk_app(mk_not_imp1_fn(), a, b, H); }`

			`expr mk_not_imp2_fn();`
Mark 'implicit' parameters, and move them to the beginning Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-08 04:47:58 +00:00			`/** \brief (Theorem) {a b : Bool}, H : Not(Implies(a, b)) \|- NotImp2(a, b, H) : Not(b) */`
Add more theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 18:23:04 +00:00			`inline expr NotImp2(expr const & a, expr const & b, expr const & H) { return mk_app(mk_not_imp2_fn(), a, b, H); }`

			`expr mk_conj_fn();`
Mark 'implicit' parameters, and move them to the beginning Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-08 04:47:58 +00:00			`/** \brief (Theorem) {a b : Bool}, H1 : a, H2 : b \|- Conj(a, b, H1, H2) : And(a, b) */`
Add more theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 18:23:04 +00:00			`inline expr Conj(expr const & a, expr const & b, expr const & H1, expr const & H2) { return mk_app(mk_conj_fn(), a, b, H1, H2); }`

			`expr mk_conjunct1_fn();`
Mark 'implicit' parameters, and move them to the beginning Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-08 04:47:58 +00:00			`/** \brief (Theorem) {a b : Bool}, H : And(a, b) \|- Conjunct1(a, b, H) : a */`
Add more theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 18:23:04 +00:00			`inline expr Conjunct1(expr const & a, expr const & b, expr const & H) { return mk_app(mk_conjunct1_fn(), a, b, H); }`

			`expr mk_conjunct2_fn();`
Mark 'implicit' parameters, and move them to the beginning Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-08 04:47:58 +00:00			`/** \brief (Theorem) {a b : Bool}, H : And(a, b) \|- Conjunct2(a, b, H) : b */`
Add more theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 18:23:04 +00:00			`inline expr Conjunct2(expr const & a, expr const & b, expr const & H) { return mk_app(mk_conjunct2_fn(), a, b, H); }`

			`expr mk_disj1_fn();`
			`/** \brief (Theorem) a b : Bool, H : a \|- Disj1(a, b, H) : Or(a, b) */`
			`inline expr Disj1(expr const & a, expr const & b, expr const & H) { return mk_app(mk_disj1_fn(), a, b, H); }`

			`expr mk_disj2_fn();`
Mark 'implicit' parameters, and move them to the beginning Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-08 04:47:58 +00:00			`/** \brief (Theorem) {b} a : Bool, H : b \|- Disj2(a, b, H) : Or(a, b) */`
			`inline expr Disj2(expr const & b, expr const & a, expr const & H) { return mk_app(mk_disj2_fn(), b, a, H); }`
Add more theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 18:23:04 +00:00
			`expr mk_disj_cases_fn();`
Mark 'implicit' parameters, and move them to the beginning Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-08 04:47:58 +00:00			`/** \brief (Theorem) {a b c : Bool}, H1 : Or(a,b), H2 : a -> c, H3 : b -> c \|- DisjCases(a, b, c, H1, H2, H3) : c */`
Add more theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 18:23:04 +00:00			`inline expr DisjCases(expr const & a, expr const & b, expr const & c, expr const & H1, expr const & H2, expr const & H3) { return mk_app({mk_disj_cases_fn(), a, b, c, H1, H2, H3}); }`

Move Symm and Trans back to basic_thms.cpp Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-09-07 06:47:13 +00:00			`expr mk_symm_fn();`
			`/** \brief (Theorem) {A : Type u}, {a b : A}, H : a = b \|- Symm(A, a, b, H) : b = a */`
			`inline expr Symm(expr const & A, expr const & a, expr const & b, expr const & H) { return mk_app(mk_symm_fn(), A, a, b, H); }`

			`expr mk_trans_fn();`
			`/** \brief (Theorem) {A : Type u}, {a b c : A}, H1 : a = b, H2 : b = c \|- Trans(A, a, b, c, H1, H2) : a = c */`
			`inline expr Trans(expr const & A, expr const & a, expr const & b, expr const & c, expr const & H1, expr const & H2) { return mk_app({mk_trans_fn(), A, a, b, c, H1, H2}); }`

			`expr mk_trans_ext_fn();`
			`/** \brief (Theorem) {A : Type u}, {B : Type u}, {a : A}, {b c : B}, H1 : a = b, H2 : b = c \|- TransExt(A, B, a, b, c, H1, H2) : a = c */`
			`inline expr TransExt(expr const & A, expr const & B, expr const & a, expr const & b, expr const & c, expr const & H1, expr const & H2) { return mk_app({mk_trans_ext_fn(), A, B, a, b, c, H1, H2}); }`

Add more theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 18:23:04 +00:00			`expr mk_eqt_elim_fn();`
Mark 'implicit' parameters, and move them to the beginning Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-08 04:47:58 +00:00			`/** \brief (Theorem) {a : Bool}, H : a = True \|- EqTElim(a, H) : a */`
Add more theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 18:23:04 +00:00			`inline expr EqTElim(expr const & a, expr const & H) { return mk_app(mk_eqt_elim_fn(), a, H); }`

			`expr mk_eqt_intro_fn();`
Mark 'implicit' parameters, and move them to the beginning Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-08 04:47:58 +00:00			`/** \brief (Theorem) {a : Bool}, H : a \|- EqTIntro(a, H) : a = True */`
Add more theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 18:23:04 +00:00			`inline expr EqTIntro(expr const & a, expr const & H) { return mk_app(mk_eqt_intro_fn(), a, H); }`

Refactor theorems. Add new theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 08:16:37 +00:00			`expr mk_congr1_fn();`
Mark 'implicit' parameters, and move them to the beginning Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-08 04:47:58 +00:00			`/** \brief (Theorem) {A : Type u}, {B : A -> Type u}, {f g : (Pi x : A, B x)}, a : A, H : f = g \|- Congr2(A, B, f, g, a, H) : f a = g a */`
Refactor theorems. Add new theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 08:16:37 +00:00			`inline expr Congr1(expr const & A, expr const & B, expr const & f, expr const & g, expr const & a, expr const & H) { return mk_app({mk_congr1_fn(), A, B, f, g, a, H}); }`

			`expr mk_congr2_fn();`
Mark 'implicit' parameters, and move them to the beginning Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-08 04:47:58 +00:00			`/** \brief (Theorem) {A : Type u}, {B : A -> Type u}, {a b : A}, f : (Pi x : A, B x), H : a = b \|- Congr1(A, B, f, a, b, H) : f a = f b */`
			`inline expr Congr2(expr const & A, expr const & B, expr const & a, expr const & b, expr const & f, expr const & H) { return mk_app({mk_congr2_fn(), A, B, a, b, f, H}); }`
Refactor theorems. Add new theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 08:16:37 +00:00
			`expr mk_congr_fn();`
Mark 'implicit' parameters, and move them to the beginning Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-08 04:47:58 +00:00			`/** \brief (Theorem) {A : Type u}, {B : A -> Type u}, {f g : (Pi x : A, B x)}, {a b : A}, H1 : f = g, H2 : a = b \|- Congr(A, B, f, g, a, b, H1, H2) : f a = g b */`
Refactor theorems. Add new theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 08:16:37 +00:00			`inline expr Congr(expr const & A, expr const & B, expr const & f, expr const & g, expr const & a, expr const & b, expr const & H1, expr const & H2) { return mk_app({mk_congr_fn(), A, B, f, g, a, b, H1, H2}); }`

			`expr mk_forall_elim_fn();`
Mark 'implicit' parameters, and move them to the beginning Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-08 04:47:58 +00:00			`// \brief (Theorem) {A : Type u}, {P : A -> Bool}, H : (Forall A P), a : A \|- Forallelim(A, P, H, a) : P a`
Refactor theorems. Add new theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 08:16:37 +00:00			`inline expr ForallElim(expr const & A, expr const & P, expr const & H, expr const & a) { return mk_app(mk_forall_elim_fn(), A, P, H, a); }`

			`/** \brief Add basic theorems to Environment */`
Use consistent names for import functions, and library files. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-09-13 15:58:34 +00:00			`void import_basic_thms(environment & env);`
Refactor theorems. Add new theorems. Signed-off-by: Leonardo de Moura <leonardo@microsoft.com> 2013-08-07 08:16:37 +00:00
			`#if 0`
			`expr mk_ext_fn();`
			`bool is_ext_fn(expr const & e);`
			`expr mk_foralli_fn();`
			`bool is_foralli_fn(expr const & e);`
			`expr mk_domain_inj_fn();`
			`bool is_domain_inj_fn(expr const & e);`
			`expr mk_range_inj_fn();`
			`bool is_range_inj_fn(expr const & e);`
			`#endif`
			`}`