(* Title: HOL/LList.thy
ID: $Id$
Author: Lawrence C Paulson, Cambridge University Computer Laboratory
Copyright 1994 University of Cambridge
Definition of type 'a llist by a greatest fixed point
Shares NIL, CONS, List_case with List.thy
Still needs filter and flatten functions -- hard because they need
bounds on the amount of lookahead required.
Could try (but would it work for the gfp analogue of term?)
LListD_Fun_def "LListD_Fun(A) == (%Z.diag({Numb(0)}) <++> diag(A) <**> Z)"
A nice but complex example would be [ML for the Working Programmer, page 176]
from(1) = enumerate (Lmap (Lmap(pack), makeqq(from(1),from(1))))
Previous definition of llistD_Fun was explicit:
llistD_Fun_def
"llistD_Fun(r) ==
{(LNil,LNil)} Un
(UN x. (split(%l1 l2.(LCons(x,l1),LCons(x,l2))))``r)"
*)
LList = Gfp + SList +
types
'a llist
arities
llist :: (term)term
consts
list_Fun :: ['a item set, 'a item set] => 'a item set
LListD_Fun ::
"[('a item * 'a item)set, ('a item * 'a item)set] =>
('a item * 'a item)set"
llist :: 'a item set => 'a item set
LListD :: "('a item * 'a item)set => ('a item * 'a item)set"
llistD_Fun :: "('a llist * 'a llist)set => ('a llist * 'a llist)set"
Rep_llist :: 'a llist => 'a item
Abs_llist :: 'a item => 'a llist
LNil :: 'a llist
LCons :: ['a, 'a llist] => 'a llist
llist_case :: ['b, ['a, 'a llist]=>'b, 'a llist] => 'b
LList_corec_fun :: "[nat, 'a=>unit+('b item * 'a), 'a] => 'b item"
LList_corec :: "['a, 'a => unit + ('b item * 'a)] => 'b item"
llist_corec :: "['a, 'a => unit + ('b * 'a)] => 'b llist"
Lmap :: ('a item => 'b item) => ('a item => 'b item)
lmap :: ('a=>'b) => ('a llist => 'b llist)
iterates :: ['a => 'a, 'a] => 'a llist
Lconst :: 'a item => 'a item
Lappend :: ['a item, 'a item] => 'a item
lappend :: ['a llist, 'a llist] => 'a llist
coinductive "llist(A)"
intrs
NIL_I "NIL: llist(A)"
CONS_I "[| a: A; M: llist(A) |] ==> CONS a M : llist(A)"
coinductive "LListD(r)"
intrs
NIL_I "(NIL, NIL) : LListD(r)"
CONS_I "[| (a,b): r; (M,N) : LListD(r)
|] ==> (CONS a M, CONS b N) : LListD(r)"
translations
"case p of LNil => a | LCons x l => b" == "llist_case a (%x l.b) p"
defs
(*Now used exclusively for abbreviating the coinduction rule*)
list_Fun_def "list_Fun A X ==
{z. z = NIL | (? M a. z = CONS a M & a : A & M : X)}"
LListD_Fun_def "LListD_Fun r X ==
{z. z = (NIL, NIL) |
(? M N a b. z = (CONS a M, CONS b N) &
(a, b) : r & (M, N) : X)}"
(*defining the abstract constructors*)
LNil_def "LNil == Abs_llist(NIL)"
LCons_def "LCons x xs == Abs_llist(CONS (Leaf x) (Rep_llist xs))"
llist_case_def
"llist_case c d l ==
List_case c (%x y. d (inv Leaf x) (Abs_llist y)) (Rep_llist l)"
LList_corec_fun_def
"LList_corec_fun k f ==
nat_rec (%x. {})
(%j r x. case f x of Inl u => NIL
| Inr(z,w) => CONS z (r w))
k"
LList_corec_def
"LList_corec a f == UN k. LList_corec_fun k f a"
llist_corec_def
"llist_corec a f ==
Abs_llist(LList_corec a
(%z.case f z of Inl x => Inl(x)
| Inr(v,w) => Inr(Leaf(v), w)))"
llistD_Fun_def
"llistD_Fun(r) ==
prod_fun Abs_llist Abs_llist ``
LListD_Fun (diag(range Leaf))
(prod_fun Rep_llist Rep_llist `` r)"
Lconst_def "Lconst(M) == lfp(%N. CONS M N)"
Lmap_def
"Lmap f M == LList_corec M (List_case (Inl ()) (%x M'. Inr((f(x), M'))))"
lmap_def
"lmap f l == llist_corec l (%z. case z of LNil => (Inl ())
| LCons y z => Inr(f(y), z))"
iterates_def "iterates f a == llist_corec a (%x. Inr((x, f(x))))"
(*Append generates its result by applying f, where
f((NIL,NIL)) = Inl(())
f((NIL, CONS N1 N2)) = Inr((N1, (NIL,N2))
f((CONS M1 M2, N)) = Inr((M1, (M2,N))
*)
Lappend_def
"Lappend M N == LList_corec (M,N)
(split(List_case (List_case (Inl ()) (%N1 N2. Inr((N1, (NIL,N2)))))
(%M1 M2 N. Inr((M1, (M2,N))))))"
lappend_def
"lappend l n == llist_corec (l,n)
(split(llist_case (llist_case (Inl ()) (%n1 n2. Inr((n1, (LNil,n2)))))
(%l1 l2 n. Inr((l1, (l2,n))))))"
rules
(*faking a type definition...*)
Rep_llist "Rep_llist(xs): llist(range(Leaf))"
Rep_llist_inverse "Abs_llist(Rep_llist(xs)) = xs"
Abs_llist_inverse "M: llist(range(Leaf)) ==> Rep_llist(Abs_llist(M)) = M"
end