(* Title: CCL/types
ID: $Id$
Author: Martin Coen, Cambridge University Computer Laboratory
Copyright 1992 University of Cambridge
For types.thy.
*)
open Type;
val simp_type_defs = [Subtype_def,Unit_def,Bool_def,Plus_def,Sigma_def,Pi_def,
Lift_def,Tall_def,Tex_def];
val ind_type_defs = [Nat_def,List_def];
val simp_data_defs = [one_def,inl_def,inr_def];
val ind_data_defs = [zero_def,succ_def,nil_def,cons_def];
goal Set.thy "A <= B <-> (ALL x. x:A --> x:B)";
by (fast_tac set_cs 1);
qed "subsetXH";
(*** Exhaustion Rules ***)
fun mk_XH_tac thy defs rls s = prove_goalw thy defs s (fn _ => [cfast_tac rls 1]);
val XH_tac = mk_XH_tac Type.thy simp_type_defs [];
val EmptyXH = XH_tac "a : {} <-> False";
val SubtypeXH = XH_tac "a : {x:A. P(x)} <-> (a:A & P(a))";
val UnitXH = XH_tac "a : Unit <-> a=one";
val BoolXH = XH_tac "a : Bool <-> a=true | a=false";
val PlusXH = XH_tac "a : A+B <-> (EX x:A. a=inl(x)) | (EX x:B. a=inr(x))";
val PiXH = XH_tac "a : PROD x:A. B(x) <-> (EX b. a=lam x. b(x) & (ALL x:A. b(x):B(x)))";
val SgXH = XH_tac "a : SUM x:A. B(x) <-> (EX x:A. EX y:B(x).a=<x,y>)";
val XHs = [EmptyXH,SubtypeXH,UnitXH,BoolXH,PlusXH,PiXH,SgXH];
val LiftXH = XH_tac "a : [A] <-> (a=bot | a:A)";
val TallXH = XH_tac "a : TALL X. B(X) <-> (ALL X. a:B(X))";
val TexXH = XH_tac "a : TEX X. B(X) <-> (EX X. a:B(X))";
val case_rls = XH_to_Es XHs;
(*** Canonical Type Rules ***)
fun mk_canT_tac thy xhs s = prove_goal thy s
(fn prems => [fast_tac (set_cs addIs (prems @ (xhs RL [iffD2]))) 1]);
val canT_tac = mk_canT_tac Type.thy XHs;
val oneT = canT_tac "one : Unit";
val trueT = canT_tac "true : Bool";
val falseT = canT_tac "false : Bool";
val lamT = canT_tac "[| !!x. x:A ==> b(x):B(x) |] ==> lam x. b(x) : Pi(A,B)";
val pairT = canT_tac "[| a:A; b:B(a) |] ==> <a,b>:Sigma(A,B)";
val inlT = canT_tac "a:A ==> inl(a) : A+B";
val inrT = canT_tac "b:B ==> inr(b) : A+B";
val canTs = [oneT,trueT,falseT,pairT,lamT,inlT,inrT];
(*** Non-Canonical Type Rules ***)
local
val lemma = prove_goal Type.thy "[| a:B(u); u=v |] ==> a : B(v)"
(fn prems => [cfast_tac prems 1]);
in
fun mk_ncanT_tac thy defs top_crls crls s = prove_goalw thy defs s
(fn major::prems => [(resolve_tac ([major] RL top_crls) 1),
(REPEAT_SOME (eresolve_tac (crls @ [exE,bexE,conjE,disjE]))),
(ALLGOALS (asm_simp_tac term_ss)),
(ALLGOALS (ares_tac (prems RL [lemma]) ORELSE'
etac bspec )),
(safe_tac (ccl_cs addSIs prems))]);
end;
val ncanT_tac = mk_ncanT_tac Type.thy [] case_rls case_rls;
val ifT = ncanT_tac
"[| b:Bool; b=true ==> t:A(true); b=false ==> u:A(false) |] ==> \
\ if b then t else u : A(b)";
val applyT = ncanT_tac
"[| f : Pi(A,B); a:A |] ==> f ` a : B(a)";
val splitT = ncanT_tac
"[| p:Sigma(A,B); !!x y. [| x:A; y:B(x); p=<x,y> |] ==> c(x,y):C(<x,y>) |] ==> \
\ split(p,c):C(p)";
val whenT = ncanT_tac
"[| p:A+B; !!x.[| x:A; p=inl(x) |] ==> a(x):C(inl(x)); \
\ !!y.[| y:B; p=inr(y) |] ==> b(y):C(inr(y)) |] ==> \
\ when(p,a,b) : C(p)";
val ncanTs = [ifT,applyT,splitT,whenT];
(*** Subtypes ***)
val SubtypeD1 = standard ((SubtypeXH RS iffD1) RS conjunct1);
val SubtypeD2 = standard ((SubtypeXH RS iffD1) RS conjunct2);
val prems = goal Type.thy
"[| a:A; P(a) |] ==> a : {x:A. P(x)}";
by (REPEAT (resolve_tac (prems@[SubtypeXH RS iffD2,conjI]) 1));
qed "SubtypeI";
val prems = goal Type.thy
"[| a : {x:A. P(x)}; [| a:A; P(a) |] ==> Q |] ==> Q";
by (REPEAT (resolve_tac (prems@[SubtypeD1,SubtypeD2]) 1));
qed "SubtypeE";
(*** Monotonicity ***)
Goal "mono (%X. X)";
by (REPEAT (ares_tac [monoI] 1));
qed "idM";
Goal "mono(%X. A)";
by (REPEAT (ares_tac [monoI,subset_refl] 1));
qed "constM";
val major::prems = goal Type.thy
"mono(%X. A(X)) ==> mono(%X.[A(X)])";
by (rtac (subsetI RS monoI) 1);
by (dtac (LiftXH RS iffD1) 1);
by (etac disjE 1);
by (etac (disjI1 RS (LiftXH RS iffD2)) 1);
by (rtac (disjI2 RS (LiftXH RS iffD2)) 1);
by (etac (major RS monoD RS subsetD) 1);
by (assume_tac 1);
qed "LiftM";
val prems = goal Type.thy
"[| mono(%X. A(X)); !!x X. x:A(X) ==> mono(%X. B(X,x)) |] ==> \
\ mono(%X. Sigma(A(X),B(X)))";
by (REPEAT (ares_tac ([subsetI RS monoI] @ canTs) 1 ORELSE
eresolve_tac ([bspec,exE,conjE,disjE,bexE] @ case_rls) 1 ORELSE
(resolve_tac (prems RL [monoD RS subsetD]) 1 THEN assume_tac 1) ORELSE
hyp_subst_tac 1));
qed "SgM";
val prems = goal Type.thy
"[| !!x. x:A ==> mono(%X. B(X,x)) |] ==> mono(%X. Pi(A,B(X)))";
by (REPEAT (ares_tac ([subsetI RS monoI] @ canTs) 1 ORELSE
eresolve_tac ([bspec,exE,conjE,disjE,bexE] @ case_rls) 1 ORELSE
(resolve_tac (prems RL [monoD RS subsetD]) 1 THEN assume_tac 1) ORELSE
hyp_subst_tac 1));
qed "PiM";
val prems = goal Type.thy
"[| mono(%X. A(X)); mono(%X. B(X)) |] ==> mono(%X. A(X)+B(X))";
by (REPEAT (ares_tac ([subsetI RS monoI] @ canTs) 1 ORELSE
eresolve_tac ([bspec,exE,conjE,disjE,bexE] @ case_rls) 1 ORELSE
(resolve_tac (prems RL [monoD RS subsetD]) 1 THEN assume_tac 1) ORELSE
hyp_subst_tac 1));
qed "PlusM";
(**************** RECURSIVE TYPES ******************)
(*** Conversion Rules for Fixed Points via monotonicity and Tarski ***)
Goal "mono(%X. Unit+X)";
by (REPEAT (ares_tac [PlusM,constM,idM] 1));
qed "NatM";
bind_thm("def_NatB", result() RS (Nat_def RS def_lfp_Tarski));
Goal "mono(%X.(Unit+Sigma(A,%y. X)))";
by (REPEAT (ares_tac [PlusM,SgM,constM,idM] 1));
qed "ListM";
bind_thm("def_ListB", result() RS (List_def RS def_lfp_Tarski));
bind_thm("def_ListsB", result() RS (Lists_def RS def_gfp_Tarski));
Goal "mono(%X.({} + Sigma(A,%y. X)))";
by (REPEAT (ares_tac [PlusM,SgM,constM,idM] 1));
qed "IListsM";
bind_thm("def_IListsB", result() RS (ILists_def RS def_gfp_Tarski));
val ind_type_eqs = [def_NatB,def_ListB,def_ListsB,def_IListsB];
(*** Exhaustion Rules ***)
fun mk_iXH_tac teqs ddefs rls s = prove_goalw Type.thy ddefs s
(fn _ => [resolve_tac (teqs RL [XHlemma1]) 1,
fast_tac (set_cs addSIs canTs addSEs case_rls) 1]);
val iXH_tac = mk_iXH_tac ind_type_eqs ind_data_defs [];
val NatXH = iXH_tac "a : Nat <-> (a=zero | (EX x:Nat. a=succ(x)))";
val ListXH = iXH_tac "a : List(A) <-> (a=[] | (EX x:A. EX xs:List(A).a=x$xs))";
val ListsXH = iXH_tac "a : Lists(A) <-> (a=[] | (EX x:A. EX xs:Lists(A).a=x$xs))";
val IListsXH = iXH_tac "a : ILists(A) <-> (EX x:A. EX xs:ILists(A).a=x$xs)";
val iXHs = [NatXH,ListXH];
val icase_rls = XH_to_Es iXHs;
(*** Type Rules ***)
val icanT_tac = mk_canT_tac Type.thy iXHs;
val incanT_tac = mk_ncanT_tac Type.thy [] icase_rls case_rls;
val zeroT = icanT_tac "zero : Nat";
val succT = icanT_tac "n:Nat ==> succ(n) : Nat";
val nilT = icanT_tac "[] : List(A)";
val consT = icanT_tac "[| h:A; t:List(A) |] ==> h$t : List(A)";
val icanTs = [zeroT,succT,nilT,consT];
val ncaseT = incanT_tac
"[| n:Nat; n=zero ==> b:C(zero); \
\ !!x.[| x:Nat; n=succ(x) |] ==> c(x):C(succ(x)) |] ==> \
\ ncase(n,b,c) : C(n)";
val lcaseT = incanT_tac
"[| l:List(A); l=[] ==> b:C([]); \
\ !!h t.[| h:A; t:List(A); l=h$t |] ==> c(h,t):C(h$t) |] ==> \
\ lcase(l,b,c) : C(l)";
val incanTs = [ncaseT,lcaseT];
(*** Induction Rules ***)
val ind_Ms = [NatM,ListM];
fun mk_ind_tac ddefs tdefs Ms canTs case_rls s = prove_goalw Type.thy ddefs s
(fn major::prems => [resolve_tac (Ms RL ([major] RL (tdefs RL [def_induct]))) 1,
fast_tac (set_cs addSIs (prems @ canTs) addSEs case_rls) 1]);
val ind_tac = mk_ind_tac ind_data_defs ind_type_defs ind_Ms canTs case_rls;
val Nat_ind = ind_tac
"[| n:Nat; P(zero); !!x.[| x:Nat; P(x) |] ==> P(succ(x)) |] ==> \
\ P(n)";
val List_ind = ind_tac
"[| l:List(A); P([]); \
\ !!x xs.[| x:A; xs:List(A); P(xs) |] ==> P(x$xs) |] ==> \
\ P(l)";
val inds = [Nat_ind,List_ind];
(*** Primitive Recursive Rules ***)
fun mk_prec_tac inds s = prove_goal Type.thy s
(fn major::prems => [resolve_tac ([major] RL inds) 1,
ALLGOALS (simp_tac term_ss THEN'
fast_tac (set_cs addSIs prems))]);
val prec_tac = mk_prec_tac inds;
val nrecT = prec_tac
"[| n:Nat; b:C(zero); \
\ !!x g.[| x:Nat; g:C(x) |] ==> c(x,g):C(succ(x)) |] ==> \
\ nrec(n,b,c) : C(n)";
val lrecT = prec_tac
"[| l:List(A); b:C([]); \
\ !!x xs g.[| x:A; xs:List(A); g:C(xs) |] ==> c(x,xs,g):C(x$xs) |] ==> \
\ lrec(l,b,c) : C(l)";
val precTs = [nrecT,lrecT];
(*** Theorem proving ***)
val [major,minor] = goal Type.thy
"[| <a,b> : Sigma(A,B); [| a:A; b:B(a) |] ==> P \
\ |] ==> P";
by (rtac (major RS (XH_to_E SgXH)) 1);
by (rtac minor 1);
by (ALLGOALS (fast_tac term_cs));
qed "SgE2";
(* General theorem proving ignores non-canonical term-formers, *)
(* - intro rules are type rules for canonical terms *)
(* - elim rules are case rules (no non-canonical terms appear) *)
val type_cs = term_cs addSIs (SubtypeI::(canTs @ icanTs))
addSEs (SubtypeE::(XH_to_Es XHs));
(*** Infinite Data Types ***)
val [mono] = goal Type.thy "mono(f) ==> lfp(f) <= gfp(f)";
by (rtac (lfp_lowerbound RS subset_trans) 1);
by (rtac (mono RS gfp_lemma3) 1);
by (rtac subset_refl 1);
qed "lfp_subset_gfp";
val prems = goal Type.thy
"[| a:A; !!x X.[| x:A; ALL y:A. t(y):X |] ==> t(x) : B(X) |] ==> \
\ t(a) : gfp(B)";
by (rtac coinduct 1);
by (res_inst_tac [("P","%x. EX y:A. x=t(y)")] CollectI 1);
by (ALLGOALS (fast_tac (ccl_cs addSIs prems)));
qed "gfpI";
val rew::prem::prems = goal Type.thy
"[| C==gfp(B); a:A; !!x X.[| x:A; ALL y:A. t(y):X |] ==> t(x) : B(X) |] ==> \
\ t(a) : C";
by (rewtac rew);
by (REPEAT (ares_tac ((prem RS gfpI)::prems) 1));
qed "def_gfpI";
(* EG *)
val prems = goal Type.thy
"letrec g x be zero$g(x) in g(bot) : Lists(Nat)";
by (rtac (refl RS (XH_to_I UnitXH) RS (Lists_def RS def_gfpI)) 1);
by (stac letrecB 1);
by (rewtac cons_def);
by (fast_tac type_cs 1);
result();