/usr/share/hol88-2.02.19940316/Library/pair/syn.ml is in hol88-library-source 2.02.19940316-19.
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% Copyright (c) Jim Grundy 1992 %
% All rights reserved %
% %
% Jim Grundy, hereafter referred to as `the Author', retains the %
% copyright and all other legal rights to the Software contained in %
% this file, hereafter referred to as `the Software'. %
% %
% The Software is made available free of charge on an `as is' basis. %
% No guarantee, either express or implied, of maintenance, reliability %
% or suitability for any purpose is made by the Author. %
% %
% The user is granted the right to make personal or internal use %
% of the Software provided that both: %
% 1. The Software is not used for commercial gain. %
% 2. The user shall not hold the Author liable for any consequences %
% arising from use of the Software. %
% %
% The user is granted the right to further distribute the Software %
% provided that both: %
% 1. The Software and this statement of rights is not modified. %
% 2. The Software does not form part or the whole of a system %
% distributed for commercial gain. %
% %
% The user is granted the right to modify the Software for personal or %
% internal use provided that all of the following conditions are %
% observed: %
% 1. The user does not distribute the modified software. %
% 2. The modified software is not used for commercial gain. %
% 3. The Author retains all rights to the modified software. %
% %
% Anyone seeking a licence to use this software for commercial purposes %
% is invited to contact the Author. %
% --------------------------------------------------------------------- %
% CONTENTS: functions on the syntax of paired abstractions and %
% quantifications. %
% --------------------------------------------------------------------- %
%$Id: syn.ml,v 3.1 1993/12/07 14:42:10 jg Exp $%
% ===================================================================== %
% Constructors for paired HOL syntax. %
% ===================================================================== %
let mk_pabs =
let mk_uncurry cf =
let tycf = type_of cf in
let uncurry_type ty =
let (tycon1, [tya; tyb]) = (dest_type ty) in
let (tycon2, [tyba; tybb]) = (dest_type tyb) in
assert (curry $= `fun`) tycon1 ;
assert (curry $= `fun`) tycon2 ;
mk_type (`fun`, [mk_type(`prod`,[tya;tyba]); tybb ])
in
mk_comb
( mk_const(`UNCURRY`,mk_type(`fun`,[tycf;uncurry_type tycf])) ,
cf )
in
letrec mpa (p,t) =
if is_var p then
mk_abs (p, t)
else % is_pair p %
let (v1,v2) = dest_pair p in
mk_uncurry (mpa (v1, (mpa (v2, t))))
in
\pt. mpa pt ? failwith `mk_pabs`;;
let mk_pforall (x,t) =
let ty = type_of x in
let allty = mk_type(`fun`,[mk_type(`fun`,[ty;bool_ty]);bool_ty]) in
mk_comb(mk_const(`!`,allty),mk_pabs(x,t)) ? failwith `mk_pforall`;;
let mk_pexists (x,t) =
let ty = type_of x in
let exty = mk_type(`fun`,[mk_type(`fun`,[ty;bool_ty]);bool_ty]) in
mk_comb(mk_const(`?`,exty),mk_pabs(x,t)) ? failwith `mk_pexists`;;
let mk_pselect (x,t) =
let ty = type_of x in
let selty = mk_type(`fun`,[mk_type(`fun`,[ty;bool_ty]);ty]) in
mk_comb(mk_const(`@`, selty), mk_pabs(x,t)) ? failwith `mk_pselect`;;
% ===================================================================== %
% Destructors for paired HOL syntax. %
% ===================================================================== %
letrec dest_pabs tm =
(if (is_abs tm) then
dest_abs tm
else if fst (dest_const (rator tm)) = `UNCURRY` then
let (v1,b1) = dest_pabs (rand tm) in
let (v2,b2) = dest_pabs b1 in
(mk_pair(v1,v2), b2)
else fail) ? failwith `dest_pabs`;;
let dest_pforall =
let check = assert (\c. fst(dest_const c) = `!`) in
\tm. (let (_,b) = (check # I) (dest_comb tm) in dest_pabs b) ?
failwith `dest_pforall`;;
let dest_pexists =
let check = assert (\c. fst(dest_const c) = `?`) in
\tm. (let (_,b) = (check # I) (dest_comb tm) in dest_pabs b) ?
failwith `dest_pexists`;;
let dest_pselect =
let check = assert (\c. fst(dest_const c) = `@`) in
\tm. (let (_,b) = (check # I) (dest_comb tm) in dest_pabs b) ?
failwith `dest_pselect`;;
% ===================================================================== %
% Discriminators for paired HOL syntax. %
% ===================================================================== %
let is_pabs = can dest_pabs and
is_pforall = can dest_pforall and
is_pexists = can dest_pexists and
is_pselect = can dest_pselect;;
% ===================================================================== %
% All the elements in a pair struture. %
% ===================================================================== %
letrec rip_pair p = ($@ ((rip_pair # rip_pair) (dest_pair p))) ? [p];;
% ===================================================================== %
% Check if a term is a pair structure of variables. %
% ===================================================================== %
let is_pvar = (forall is_var) o rip_pair ;;
% ===================================================================== %
% Paired version of variant. %
% ===================================================================== %
let pvariant =
letrec uniq l =
if null l then
[]
else
let (h.t) = l in
h.(uniq (filter (\e. not (e = h)) t)) in
letrec variantl avl vl =
if null vl then
[]
else
let (h.t) = vl in
let h' = (variant (avl@(filter is_var t)) h) in
(h',h).(variantl (h'.avl) t)
in
\pl p.
let avoid = (flat (map ((map (assert is_var)) o rip_pair) pl)) in
let originals =
uniq (map (assert (\p. (is_var p) or (is_const p))) (rip_pair p)) in
let sub = variantl avoid originals in
subst sub p;;
% ===================================================================== %
% Generates a pair structure of variable with the same structure as %
% its parameter. %
% ===================================================================== %
letrec genlike p =
if is_pair p then
mk_pair ((genlike # genlike) (dest_pair p))
else
genvar (type_of p);;
% ===================================================================== %
% Iterated paired constructors: %
% %
% * list_mk_pabs ([p1;...;pn],t) ---> "\p1 ... pn.t" %
% * list_mk_pforall ([p1;...;pn],t) ---> "!p1 ... pn.t" %
% * list_mk_pexists ([p1;...;pn],t) ---> "?p1 ... pn.t" %
% ===================================================================== %
let list_mk_pabs (pl, t) =
(itlist (curry mk_pabs) pl t) ? failwith `list_mk_pabs`;;
let list_mk_pforall (pl, t) =
(itlist (curry mk_pforall) pl t) ? failwith `list_mk_pforall`;;
let list_mk_pexists (pl, t) =
(itlist (curry mk_pexists) pl t) ? failwith `list_mk_pexists`;;
% ===================================================================== %
% Iterated paired destructors: %
% %
% * strip_abs "\p1 ... pn. t" ---> [p1; ...; pn], t %
% * strip_forall "!p1 ... pn. t" ---> [p1; ...; pn], t %
% * strip_exists "?p1 ... pn. t" ---> [p1; ...; pn], t %
% ===================================================================== %
letrec strip_pabs tm =
(let (bp,body) = dest_pabs tm in
let (bps,core) = strip_pabs body in
(bp.bps, core))
? ([],tm);;
letrec strip_pforall tm =
(let (bp,body) = dest_pforall tm in
let (bps,core) = strip_pforall body in
(bp.bps,core))
? ([],tm);;
letrec strip_pexists tm =
(let (bp,body) = dest_pexists tm in
let (bps,core) = strip_pexists body in
(bp.bps,core))
? ([],tm);;
% ===================================================================== %
% Paired bound variable and body. %
% ===================================================================== %
let bndpair tm = fst (dest_pabs tm) ? failwith `bndpair`
and pbody tm = snd (dest_pabs tm) ? failwith `pbody` ;;
% ===================================================================== %
% Occurence check for bound pairs. %
% occs_in p t true iff any of the variables in p occure free in t %
% ===================================================================== %
let occs_in =
letrec occs_check vl t =
if is_const t then
false
else if is_var t then
mem t vl
else if is_comb t then
let (t1,t2) = dest_comb t in
(occs_check vl t1) or (occs_check vl t2)
else % is_abs %
let (x,b) = dest_abs t in
occs_check (filter (\v. (not (v = x))) vl) b
in
\p t.
if is_pvar p then
let vs = frees p in
occs_check vs t
else
failwith `occs_in: not a pvar`;;
% ===================================================================== %
% Extra support of manipulating product types. %
% ===================================================================== %
let is_prod t =
let (ty_name, l) = dest_type t in
((ty_name = `prod`) & ((length l) = 2)) ;;
let dest_prod t =
(let (ty_name, [ty1;ty2]) = dest_type t in
if ty_name = `prod` then
(ty1,ty2)
else
fail
) ? failwith `dest_prod`;;
let mk_prod (ty1,ty2) = mk_type (`prod`,[ty1;ty2]);;
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