src/HOLCF/Tools/domain/domain_library.ML
author paulson
Fri, 05 Oct 2007 09:59:03 +0200
changeset 24854 0ebcd575d3c6
parent 24680 0d355aa59e67
child 25701 73fbe868b4e7
permissions -rw-r--r--
filtering out some package theorems

(*  Title:      HOLCF/Tools/domain/domain_library.ML
    ID:         $Id$
    Author:     David von Oheimb

Library for domain command.
*)


(* ----- general support ---------------------------------------------------- *)

fun mapn f n []      = []
|   mapn f n (x::xs) = (f n x) :: mapn f (n+1) xs;

fun foldr'' f (l,f2) = let fun itr []  = raise Fail "foldr''"
			     | itr [a] = f2 a
			     | itr (a::l) = f(a, itr l)
in  itr l  end;
fun map_cumulr f start xs = foldr (fn (x,(ys,res))=>case f(x,res) of (y,res2) =>
						  (y::ys,res2)) ([],start) xs;


fun first  (x,_,_) = x; fun second (_,x,_) = x; fun third  (_,_,x) = x;
fun upd_first  f (x,y,z) = (f x,   y,   z);
fun upd_second f (x,y,z) = (  x, f y,   z);
fun upd_third  f (x,y,z) = (  x,   y, f z);

fun atomize thm = let val r_inst = read_instantiate;
    fun at  thm = case concl_of thm of
      _$(Const("op &",_)$_$_)       => at(thm RS conjunct1)@at(thm RS conjunct2)
    | _$(Const("All" ,_)$Abs(s,_,_))=> at(thm RS (r_inst [("x","?"^s)] spec))
    | _				    => [thm];
in map zero_var_indexes (at thm) end;

(* ----- specific support for domain ---------------------------------------- *)

structure Domain_Library = struct

open HOLCFLogic;

exception Impossible of string;
fun Imposs msg = raise Impossible ("Domain:"^msg);

(* ----- name handling ----- *)

val strip_esc = let fun strip ("'" :: c :: cs) = c :: strip cs
		    |   strip ["'"] = []
		    |   strip (c :: cs) = c :: strip cs
		    |   strip [] = [];
in implode o strip o Symbol.explode end;

fun extern_name con = case Symbol.explode con of 
		   ("o"::"p"::" "::rest) => implode rest
		   | _ => con;
fun dis_name  con = "is_"^ (extern_name con);
fun dis_name_ con = "is_"^ (strip_esc   con);
fun mat_name  con = "match_"^ (extern_name con);
fun mat_name_ con = "match_"^ (strip_esc   con);
fun pat_name  con = (extern_name con) ^ "_pat";
fun pat_name_ con = (strip_esc   con) ^ "_pat";

(* make distinct names out of the type list, 
   forbidding "o","n..","x..","f..","P.." as names *)
(* a number string is added if necessary *)
fun mk_var_names ids : string list = let
    fun nonreserved s = if s mem ["n","x","f","P"] then s^"'" else s;
    fun index_vnames(vn::vns,occupied) =
          (case AList.lookup (op =) occupied vn of
             NONE => if vn mem vns
                     then (vn^"1") :: index_vnames(vns,(vn,1)  ::occupied)
                     else  vn      :: index_vnames(vns,          occupied)
           | SOME(i) => (vn^(string_of_int (i+1)))
				   :: index_vnames(vns,(vn,i+1)::occupied))
      | index_vnames([],occupied) = [];
in index_vnames(map nonreserved ids, [("O",0),("o",0)]) end;

fun pcpo_type sg t = Sign.of_sort sg (Sign.certify_typ sg t, pcpoS);
fun string_of_typ sg = Sign.string_of_typ sg o Sign.certify_typ sg;

(* ----- constructor list handling ----- *)

type cons = (string *				(* operator name of constr *)
	    ((bool*int*DatatypeAux.dtyp)*	(*  (lazy,recursive element or ~1) *)
	      string option*			(*   selector name    *)
	      string)				(*   argument name    *)
	    list);				(* argument list      *)
type eq = (string *		(* name      of abstracted type *)
	   typ list) *		(* arguments of abstracted type *)
	  cons list;		(* represented type, as a constructor list *)

fun rec_of arg  = second (first arg);
fun is_lazy arg = first (first arg);
val sel_of    =       second;
val     vname =       third;
val upd_vname =   upd_third;
fun is_rec         arg = rec_of arg >=0;
fun is_nonlazy_rec arg = is_rec arg andalso not (is_lazy arg);
fun nonlazy     args   = map vname (filter_out is_lazy    args);
fun nonlazy_rec args   = map vname (List.filter is_nonlazy_rec args);

(* ----- qualified names of HOLCF constants ----- *)

val lessN      = @{const_name Porder.sq_le};
val UU_N       = "Pcpo.UU";
val admN       = "Adm.adm";
val compactN   = "Adm.compact";
val Rep_CFunN  = "Cfun.Rep_CFun";
val Abs_CFunN  = "Cfun.Abs_CFun";
val ID_N       = "Cfun.ID";
val cfcompN    = "Cfun.cfcomp";
val strictifyN = "Cfun.strictify";
val cpairN     = "Cprod.cpair";
val cfstN      = "Cprod.cfst";
val csndN      = "Cprod.csnd";
val csplitN    = "Cprod.csplit";
val spairN     = "Sprod.spair";
val sfstN      = "Sprod.sfst";
val ssndN      = "Sprod.ssnd";
val ssplitN    = "Sprod.ssplit";
val sinlN      = "Ssum.sinl";
val sinrN      = "Ssum.sinr";
val sscaseN    = "Ssum.sscase";
val upN        = "Up.up";
val fupN       = "Up.fup";
val ONE_N      = "One.ONE";
val TT_N       = "Tr.TT";
val FF_N       = "Tr.FF";
val iterateN   = "Fix.iterate";
val fixN       = "Fix.fix";
val returnN    = "Fixrec.return";
val failN      = "Fixrec.fail";
val cpair_patN = "Fixrec.cpair_pat";
val branchN    = "Fixrec.branch";

val pcpoN      = "Pcpo.pcpo"
val pcpoS      = [pcpoN];


(* ----- support for type and mixfix expressions ----- *)

infixr 5 -->;

(* ----- support for term expressions ----- *)

fun %: s = Free(s,dummyT);
fun %# arg = %:(vname arg);
fun %%: s = Const(s,dummyT);

local open HOLogic in
val mk_trp = mk_Trueprop;
fun mk_conj (S,T) = conj $ S $ T;
fun mk_disj (S,T) = disj $ S $ T;
fun mk_imp  (S,T) = imp  $ S $ T;
fun mk_lam  (x,T) = Abs(x,dummyT,T);
fun mk_all  (x,P) = HOLogic.mk_all (x,dummyT,P);
fun mk_ex   (x,P) = mk_exists (x,dummyT,P);
val mk_constrain = uncurry TypeInfer.constrain;
fun mk_constrainall (x,typ,P) = %%:"All" $ (TypeInfer.constrain (typ --> boolT) (mk_lam(x,P)));
end

fun mk_All  (x,P) = %%:"all" $ mk_lam(x,P); (* meta universal quantification *)

infixr 0 ===>;  fun S ===> T = %%:"==>" $ S $ T;
infixr 0 ==>;   fun S ==> T = mk_trp S ===> mk_trp T;
infix 0 ==;     fun S ==  T = %%:"==" $ S $ T;
infix 1 ===;    fun S === T = %%:"op =" $ S $ T;
infix 1 ~=;     fun S ~=  T = HOLogic.mk_not (S === T);
infix 1 <<;     fun S <<  T = %%:lessN $ S $ T;
infix 1 ~<<;    fun S ~<< T = HOLogic.mk_not (S << T);

infix 9 `  ; fun f`  x = %%:Rep_CFunN $ f $ x;
infix 9 `% ; fun f`% s = f` %: s;
infix 9 `%%; fun f`%%s = f` %%:s;
val list_ccomb = Library.foldl (op `); (* continuous version of list_comb *)
fun con_app2 con f args = list_ccomb(%%:con,map f args);
fun con_app con = con_app2 con %#;
fun if_rec  arg f y   = if is_rec arg then f (rec_of arg) else y;
fun app_rec_arg p arg = if_rec arg (fn n => fn x => (p n)`x) I (%# arg);
fun prj _  _  x (   _::[]) _ = x
|   prj f1 _  x (_::y::ys) 0 = f1 x y
|   prj f1 f2 x (y::   ys) j = prj f1 f2 (f2 x y) ys (j-1);
fun  proj x      = prj (fn S => K(%%:"fst" $S)) (fn S => K(%%:"snd" $S)) x;
fun cproj x      = prj (fn S => K(%%:cfstN`S)) (fn S => K(%%:csndN`S)) x;
fun lift tfn = Library.foldr (fn (x,t)=> (mk_trp(tfn x) ===> t));

fun /\ v T = %%:Abs_CFunN $ mk_lam(v,T);
fun /\# (arg,T) = /\ (vname arg) T;
infixr 9 oo; fun S oo T = %%:cfcompN`S`T;
val UU = %%:UU_N;
fun strict f = f`UU === UU;
fun defined t = t ~= UU;
fun cpair (t,u) = %%:cpairN`t`u;
fun spair (t,u) = %%:spairN`t`u;
fun mk_ctuple [] = HOLogic.unit (* used in match_defs *)
|   mk_ctuple ts = foldr1 cpair ts;
fun mk_stuple [] = %%:ONE_N
|   mk_stuple ts = foldr1 spair ts;
fun mk_ctupleT [] = HOLogic.unitT   (* used in match_defs *)
|   mk_ctupleT Ts = foldr1 HOLogic.mk_prodT Ts;
fun mk_maybeT T = Type ("Fixrec.maybe",[T]);
fun cpair_pat (p1,p2) = %%:cpair_patN $ p1 $ p2;
fun lift_defined f = lift (fn x => defined (f x));
fun bound_arg vns v = Bound(length vns -find_index_eq v vns -1);

fun cont_eta_contract (Const("Cfun.Abs_CFun",TT) $ Abs(a,T,body)) = 
      (case cont_eta_contract body  of
        body' as (Const("Cfun.Rep_CFun",Ta) $ f $ Bound 0) => 
	  if not (0 mem loose_bnos f) then incr_boundvars ~1 f 
	  else   Const("Cfun.Abs_CFun",TT) $ Abs(a,T,body')
      | body' => Const("Cfun.Abs_CFun",TT) $ Abs(a,T,body'))
|   cont_eta_contract(f$t) = cont_eta_contract f $ cont_eta_contract t
|   cont_eta_contract t    = t;

fun idx_name dnames s n = s^(if length dnames = 1 then "" else string_of_int n);
fun when_funs cons = if length cons = 1 then ["f"] 
                     else mapn (fn n => K("f"^(string_of_int n))) 1 cons;
fun when_body cons funarg = let
	fun one_fun n (_,[]  ) = /\ "dummy" (funarg(1,n))
	|   one_fun n (_,args) = let
		val l2 = length args;
		fun idxs m arg = (if is_lazy arg then fn x=> %%:fupN` %%:ID_N`x
					         else I) (Bound(l2-m));
		in cont_eta_contract (foldr'' 
			(fn (a,t) => %%:ssplitN`(/\# (a,t)))
			(args,
			fn a=> /\#(a,(list_ccomb(funarg(l2,n),mapn idxs 1 args))))
			) end;
in (if length cons = 1 andalso length(snd(hd cons)) <= 1
    then fn t => %%:strictifyN`t else I)
     (foldr1 (fn (x,y)=> %%:sscaseN`x`y) (mapn one_fun 1 cons)) end;
end; (* struct *)