--- a/src/ZF/Pair.ML Sat Apr 05 16:18:58 2003 +0200
+++ /dev/null Thu Jan 01 00:00:00 1970 +0000
@@ -1,146 +0,0 @@
-(* Title: ZF/pair
- ID: $Id$
- Author: Lawrence C Paulson, Cambridge University Computer Laboratory
- Copyright 1992 University of Cambridge
-
-Ordered pairs in Zermelo-Fraenkel Set Theory
-*)
-
-(** Lemmas for showing that <a,b> uniquely determines a and b **)
-
-val doubleton_iff = prove_goal ZF.thy
- "{a,b} = {c,d} <-> (a=c & b=d) | (a=d & b=c)"
- (fn _=> [ (resolve_tac [extension RS iff_trans] 1),
- (fast_tac upair_cs 1) ]);
-
-val Pair_iff = prove_goalw ZF.thy [Pair_def]
- "<a,b> = <c,d> <-> a=c & b=d"
- (fn _=> [ (simp_tac (FOL_ss addsimps [doubleton_iff]) 1),
- (fast_tac FOL_cs 1) ]);
-
-val Pair_inject = standard (Pair_iff RS iffD1 RS conjE);
-
-val Pair_inject1 = prove_goal ZF.thy "<a,b> = <c,d> ==> a=c"
- (fn [major]=>
- [ (rtac (major RS Pair_inject) 1), (assume_tac 1) ]);
-
-val Pair_inject2 = prove_goal ZF.thy "<a,b> = <c,d> ==> b=d"
- (fn [major]=>
- [ (rtac (major RS Pair_inject) 1), (assume_tac 1) ]);
-
-val Pair_neq_0 = prove_goalw ZF.thy [Pair_def] "<a,b>=0 ==> P"
- (fn [major]=>
- [ (rtac (major RS equalityD1 RS subsetD RS emptyE) 1),
- (rtac consI1 1) ]);
-
-val Pair_neq_fst = prove_goalw ZF.thy [Pair_def] "<a,b>=a ==> P"
- (fn [major]=>
- [ (rtac (consI1 RS mem_anti_sym RS FalseE) 1),
- (rtac (major RS subst) 1),
- (rtac consI1 1) ]);
-
-val Pair_neq_snd = prove_goalw ZF.thy [Pair_def] "<a,b>=b ==> P"
- (fn [major]=>
- [ (rtac (consI1 RS consI2 RS mem_anti_sym RS FalseE) 1),
- (rtac (major RS subst) 1),
- (rtac (consI1 RS consI2) 1) ]);
-
-
-(*** Sigma: Disjoint union of a family of sets
- Generalizes Cartesian product ***)
-
-val SigmaI = prove_goalw ZF.thy [Sigma_def]
- "[| a:A; b:B(a) |] ==> <a,b> : Sigma(A,B)"
- (fn prems=> [ (REPEAT (resolve_tac (prems@[singletonI,UN_I]) 1)) ]);
-
-(*The general elimination rule*)
-val SigmaE = prove_goalw ZF.thy [Sigma_def]
- "[| c: Sigma(A,B); \
-\ !!x y.[| x:A; y:B(x); c=<x,y> |] ==> P \
-\ |] ==> P"
- (fn major::prems=>
- [ (cut_facts_tac [major] 1),
- (REPEAT (eresolve_tac [UN_E, singletonE] 1 ORELSE ares_tac prems 1)) ]);
-
-(** Elimination of <a,b>:A*B -- introduces no eigenvariables **)
-val SigmaD1 = prove_goal ZF.thy "<a,b> : Sigma(A,B) ==> a : A"
- (fn [major]=>
- [ (rtac (major RS SigmaE) 1),
- (REPEAT (eresolve_tac [asm_rl,Pair_inject,ssubst] 1)) ]);
-
-val SigmaD2 = prove_goal ZF.thy "<a,b> : Sigma(A,B) ==> b : B(a)"
- (fn [major]=>
- [ (rtac (major RS SigmaE) 1),
- (REPEAT (eresolve_tac [asm_rl,Pair_inject,ssubst] 1)) ]);
-
-(*Also provable via
- rule_by_tactic (REPEAT_FIRST (etac Pair_inject ORELSE' bound_hyp_subst_tac)
- THEN prune_params_tac)
- (read_instantiate [("c","<a,b>")] SigmaE); *)
-val SigmaE2 = prove_goal ZF.thy
- "[| <a,b> : Sigma(A,B); \
-\ [| a:A; b:B(a) |] ==> P \
-\ |] ==> P"
- (fn [major,minor]=>
- [ (rtac minor 1),
- (rtac (major RS SigmaD1) 1),
- (rtac (major RS SigmaD2) 1) ]);
-
-val Sigma_cong = prove_goalw ZF.thy [Sigma_def]
- "[| A=A'; !!x. x:A' ==> B(x)=B'(x) |] ==> \
-\ Sigma(A,B) = Sigma(A',B')"
- (fn prems=> [ (simp_tac (FOL_ss addsimps prems addcongs [RepFun_cong]) 1) ]);
-
-val Sigma_empty1 = prove_goal ZF.thy "Sigma(0,B) = 0"
- (fn _ => [ (fast_tac (lemmas_cs addIs [equalityI] addSEs [SigmaE]) 1) ]);
-
-val Sigma_empty2 = prove_goal ZF.thy "A*0 = 0"
- (fn _ => [ (fast_tac (lemmas_cs addIs [equalityI] addSEs [SigmaE]) 1) ]);
-
-
-(*** Eliminator - split ***)
-
-val split = prove_goalw ZF.thy [split_def]
- "split(%x y.c(x,y), <a,b>) = c(a,b)"
- (fn _ =>
- [ (fast_tac (upair_cs addIs [the_equality] addEs [Pair_inject]) 1) ]);
-
-val split_type = prove_goal ZF.thy
- "[| p:Sigma(A,B); \
-\ !!x y.[| x:A; y:B(x) |] ==> c(x,y):C(<x,y>) \
-\ |] ==> split(%x y.c(x,y), p) : C(p)"
- (fn major::prems=>
- [ (rtac (major RS SigmaE) 1),
- (etac ssubst 1),
- (REPEAT (ares_tac (prems @ [split RS ssubst]) 1)) ]);
-
-(*** conversions for fst and snd ***)
-
-val fst_conv = prove_goalw ZF.thy [fst_def] "fst(<a,b>) = a"
- (fn _=> [ (rtac split 1) ]);
-
-val snd_conv = prove_goalw ZF.thy [snd_def] "snd(<a,b>) = b"
- (fn _=> [ (rtac split 1) ]);
-
-
-(*** split for predicates: result type o ***)
-
-goalw ZF.thy [fsplit_def] "!!R a b. R(a,b) ==> fsplit(R, <a,b>)";
-by (REPEAT (ares_tac [refl,exI,conjI] 1));
-val fsplitI = result();
-
-val major::prems = goalw ZF.thy [fsplit_def]
- "[| fsplit(R,z); !!x y. [| z = <x,y>; R(x,y) |] ==> P |] ==> P";
-by (cut_facts_tac [major] 1);
-by (REPEAT (eresolve_tac (prems@[asm_rl,exE,conjE]) 1));
-val fsplitE = result();
-
-goal ZF.thy "!!R a b. fsplit(R,<a,b>) ==> R(a,b)";
-by (REPEAT (eresolve_tac [asm_rl,fsplitE,Pair_inject,ssubst] 1));
-val fsplitD = result();
-
-val pair_cs = upair_cs
- addSIs [SigmaI]
- addSEs [SigmaE2, SigmaE, Pair_inject, make_elim succ_inject,
- Pair_neq_0, sym RS Pair_neq_0, succ_neq_0, sym RS succ_neq_0];
-