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src/HOL/Inductive.ML
author clasohm
Tue, 21 Nov 1995 12:41:52 +0100
changeset 1350 5bf4a54ba25f
parent 923 ff1574a81019
child 1430 439e1476a7f8
permissions -rw-r--r--
replaced exit_use by exit_use_dir for subdirectories

(*  Title: 	HOL/inductive.ML
    ID:         $Id$
    Author: 	Lawrence C Paulson, Cambridge University Computer Laboratory
    Copyright   1993  University of Cambridge

(Co)Inductive Definitions for HOL

Inductive definitions use least fixedpoints with standard products and sums
Coinductive definitions use greatest fixedpoints with Quine products and sums

Sums are used only for mutual recursion;
Products are used only to derive "streamlined" induction rules for relations
*)

local open Ind_Syntax
in

fun gen_fp_oper a (X,T,t) = 
    let val setT = mk_setT T
    in Const(a, (setT-->setT)-->setT) $ absfree(X, setT, t)  end;

structure Lfp_items =
  struct
  val oper	= gen_fp_oper "lfp"
  val Tarski	= def_lfp_Tarski
  val induct	= def_induct
  end;

structure Gfp_items =
  struct
  val oper	= gen_fp_oper "gfp"
  val Tarski	= def_gfp_Tarski
  val induct	= def_Collect_coinduct
  end;

end;


functor Ind_section_Fun (Inductive: sig include INDUCTIVE_ARG INDUCTIVE_I end) 
  : sig include INTR_ELIM INDRULE end =
struct
structure Intr_elim = Intr_elim_Fun(structure Inductive=Inductive and 
				    Fp=Lfp_items);

structure Indrule = Indrule_Fun
    (structure Inductive=Inductive and Intr_elim=Intr_elim);

open Intr_elim Indrule
end;


structure Ind = Add_inductive_def_Fun (Lfp_items);


signature INDUCTIVE_STRING =
  sig
  val thy_name   : string 		(*name of the new theory*)
  val srec_tms   : string list		(*recursion terms*)
  val sintrs     : string list		(*desired introduction rules*)
  end;


(*For upwards compatibility: can be called directly from ML*)
functor Inductive_Fun
 (Inductive: sig include INDUCTIVE_STRING INDUCTIVE_ARG end)
   : sig include INTR_ELIM INDRULE end =
Ind_section_Fun
   (open Inductive Ind_Syntax
    val sign = sign_of thy;
    val rec_tms = map (readtm sign termTVar) srec_tms
    and intr_tms = map (readtm sign propT) sintrs;
    val thy = thy |> Ind.add_fp_def_i(rec_tms, intr_tms) 
                  |> add_thyname thy_name);



signature COINDRULE =
  sig
  val coinduct : thm
  end;


functor CoInd_section_Fun
 (Inductive: sig include INDUCTIVE_ARG INDUCTIVE_I end) 
    : sig include INTR_ELIM COINDRULE end =
struct
structure Intr_elim = Intr_elim_Fun(structure Inductive=Inductive and Fp=Gfp_items);

open Intr_elim 
val coinduct = raw_induct
end;


structure CoInd = Add_inductive_def_Fun(Gfp_items);
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