--- a/Fun.ML Tue Oct 24 14:59:17 1995 +0100
+++ /dev/null Thu Jan 01 00:00:00 1970 +0000
@@ -1,200 +0,0 @@
-(* Title: HOL/Fun
- ID: $Id$
- Author: Tobias Nipkow, Cambridge University Computer Laboratory
- Copyright 1993 University of Cambridge
-
-Lemmas about functions.
-*)
-
-goal Fun.thy "(f = g) = (!x. f(x)=g(x))";
-by (rtac iffI 1);
-by(asm_simp_tac HOL_ss 1);
-by(rtac ext 1 THEN asm_simp_tac HOL_ss 1);
-qed "expand_fun_eq";
-
-val prems = goal Fun.thy
- "[| f(x)=u; !!x. P(x) ==> g(f(x)) = x; P(x) |] ==> x=g(u)";
-by (rtac (arg_cong RS box_equals) 1);
-by (REPEAT (resolve_tac (prems@[refl]) 1));
-qed "apply_inverse";
-
-
-(*** Range of a function ***)
-
-(*Frequently b does not have the syntactic form of f(x).*)
-val [prem] = goalw Fun.thy [range_def] "b=f(x) ==> b : range(f)";
-by (EVERY1 [rtac CollectI, rtac exI, rtac prem]);
-qed "range_eqI";
-
-val rangeI = refl RS range_eqI;
-
-val [major,minor] = goalw Fun.thy [range_def]
- "[| b : range(%x.f(x)); !!x. b=f(x) ==> P |] ==> P";
-by (rtac (major RS CollectD RS exE) 1);
-by (etac minor 1);
-qed "rangeE";
-
-(*** Image of a set under a function ***)
-
-val prems = goalw Fun.thy [image_def] "[| b=f(x); x:A |] ==> b : f``A";
-by (REPEAT (resolve_tac (prems @ [CollectI,bexI,prem]) 1));
-qed "image_eqI";
-
-val imageI = refl RS image_eqI;
-
-(*The eta-expansion gives variable-name preservation.*)
-val major::prems = goalw Fun.thy [image_def]
- "[| b : (%x.f(x))``A; !!x.[| b=f(x); x:A |] ==> P |] ==> P";
-by (rtac (major RS CollectD RS bexE) 1);
-by (REPEAT (ares_tac prems 1));
-qed "imageE";
-
-goalw Fun.thy [o_def] "(f o g)``r = f``(g``r)";
-by (rtac set_ext 1);
-by (fast_tac (HOL_cs addIs [imageI] addSEs [imageE]) 1);
-qed "image_compose";
-
-goal Fun.thy "f``(A Un B) = f``A Un f``B";
-by (rtac set_ext 1);
-by (fast_tac (HOL_cs addIs [imageI,UnCI] addSEs [imageE,UnE]) 1);
-qed "image_Un";
-
-(*** inj(f): f is a one-to-one function ***)
-
-val prems = goalw Fun.thy [inj_def]
- "[| !! x y. f(x) = f(y) ==> x=y |] ==> inj(f)";
-by (fast_tac (HOL_cs addIs prems) 1);
-qed "injI";
-
-val [major] = goal Fun.thy "(!!x. g(f(x)) = x) ==> inj(f)";
-by (rtac injI 1);
-by (etac (arg_cong RS box_equals) 1);
-by (rtac major 1);
-by (rtac major 1);
-qed "inj_inverseI";
-
-val [major,minor] = goalw Fun.thy [inj_def]
- "[| inj(f); f(x) = f(y) |] ==> x=y";
-by (rtac (major RS spec RS spec RS mp) 1);
-by (rtac minor 1);
-qed "injD";
-
-(*Useful with the simplifier*)
-val [major] = goal Fun.thy "inj(f) ==> (f(x) = f(y)) = (x=y)";
-by (rtac iffI 1);
-by (etac (major RS injD) 1);
-by (etac arg_cong 1);
-qed "inj_eq";
-
-val [major] = goal Fun.thy "inj(f) ==> (@x.f(x)=f(y)) = y";
-by (rtac (major RS injD) 1);
-by (rtac selectI 1);
-by (rtac refl 1);
-qed "inj_select";
-
-(*A one-to-one function has an inverse (given using select).*)
-val [major] = goalw Fun.thy [Inv_def] "inj(f) ==> Inv(f,f(x)) = x";
-by (EVERY1 [rtac (major RS inj_select)]);
-qed "Inv_f_f";
-
-(* Useful??? *)
-val [oneone,minor] = goal Fun.thy
- "[| inj(f); !!y. y: range(f) ==> P(Inv(f,y)) |] ==> P(x)";
-by (res_inst_tac [("t", "x")] (oneone RS (Inv_f_f RS subst)) 1);
-by (rtac (rangeI RS minor) 1);
-qed "inj_transfer";
-
-
-(*** inj_onto(f,A): f is one-to-one over A ***)
-
-val prems = goalw Fun.thy [inj_onto_def]
- "(!! x y. [| f(x) = f(y); x:A; y:A |] ==> x=y) ==> inj_onto(f,A)";
-by (fast_tac (HOL_cs addIs prems addSIs [ballI]) 1);
-qed "inj_ontoI";
-
-val [major] = goal Fun.thy
- "(!!x. x:A ==> g(f(x)) = x) ==> inj_onto(f,A)";
-by (rtac inj_ontoI 1);
-by (etac (apply_inverse RS trans) 1);
-by (REPEAT (eresolve_tac [asm_rl,major] 1));
-qed "inj_onto_inverseI";
-
-val major::prems = goalw Fun.thy [inj_onto_def]
- "[| inj_onto(f,A); f(x)=f(y); x:A; y:A |] ==> x=y";
-by (rtac (major RS bspec RS bspec RS mp) 1);
-by (REPEAT (resolve_tac prems 1));
-qed "inj_ontoD";
-
-goal Fun.thy "!!x y.[| inj_onto(f,A); x:A; y:A |] ==> (f(x)=f(y)) = (x=y)";
-by (fast_tac (HOL_cs addSEs [inj_ontoD]) 1);
-qed "inj_onto_iff";
-
-val major::prems = goal Fun.thy
- "[| inj_onto(f,A); ~x=y; x:A; y:A |] ==> ~ f(x)=f(y)";
-by (rtac contrapos 1);
-by (etac (major RS inj_ontoD) 2);
-by (REPEAT (resolve_tac prems 1));
-qed "inj_onto_contraD";
-
-
-(*** Lemmas about inj ***)
-
-val prems = goalw Fun.thy [o_def]
- "[| inj(f); inj_onto(g,range(f)) |] ==> inj(g o f)";
-by (cut_facts_tac prems 1);
-by (fast_tac (HOL_cs addIs [injI,rangeI]
- addEs [injD,inj_ontoD]) 1);
-qed "comp_inj";
-
-val [prem] = goal Fun.thy "inj(f) ==> inj_onto(f,A)";
-by (fast_tac (HOL_cs addIs [prem RS injD, inj_ontoI]) 1);
-qed "inj_imp";
-
-val [prem] = goalw Fun.thy [Inv_def] "y : range(f) ==> f(Inv(f,y)) = y";
-by (EVERY1 [rtac (prem RS rangeE), rtac selectI, etac sym]);
-qed "f_Inv_f";
-
-val prems = goal Fun.thy
- "[| Inv(f,x)=Inv(f,y); x: range(f); y: range(f) |] ==> x=y";
-by (rtac (arg_cong RS box_equals) 1);
-by (REPEAT (resolve_tac (prems @ [f_Inv_f]) 1));
-qed "Inv_injective";
-
-val prems = goal Fun.thy
- "[| inj(f); A<=range(f) |] ==> inj_onto(Inv(f), A)";
-by (cut_facts_tac prems 1);
-by (fast_tac (HOL_cs addIs [inj_ontoI]
- addEs [Inv_injective,injD,subsetD]) 1);
-qed "inj_onto_Inv";
-
-
-(*** Set reasoning tools ***)
-
-val set_cs = HOL_cs
- addSIs [ballI, PowI, subsetI, InterI, INT_I, INT1_I, CollectI,
- ComplI, IntI, DiffI, UnCI, insertCI]
- addIs [bexI, UnionI, UN_I, UN1_I, imageI, rangeI]
- addSEs [bexE, make_elim PowD, UnionE, UN_E, UN1_E, DiffE,
- CollectE, ComplE, IntE, UnE, insertE, imageE, rangeE, emptyE]
- addEs [ballE, InterD, InterE, INT_D, INT_E, make_elim INT1_D,
- subsetD, subsetCE];
-
-fun cfast_tac prems = cut_facts_tac prems THEN' fast_tac set_cs;
-
-
-fun prover s = prove_goal Fun.thy s (fn _=>[fast_tac set_cs 1]);
-
-val mem_simps = map prover
- [ "(a : A Un B) = (a:A | a:B)",
- "(a : A Int B) = (a:A & a:B)",
- "(a : Compl(B)) = (~a:B)",
- "(a : A-B) = (a:A & ~a:B)",
- "(a : {b}) = (a=b)",
- "(a : {x.P(x)}) = P(a)" ];
-
-val mksimps_pairs = ("Ball",[bspec]) :: mksimps_pairs;
-
-val set_ss =
- HOL_ss addsimps mem_simps
- addcongs [ball_cong,bex_cong]
- setmksimps (mksimps mksimps_pairs);