[helm.git] / helm / ocaml / cic_transformations / tacticAst2Box.ml

(* Copyright (C) 2004, HELM Team.
 * 
 * This file is part of HELM, an Hypertextual, Electronic
 * Library of Mathematics, developed at the Computer Science
 * Department, University of Bologna, Italy.
 * 
 * HELM is free software; you can redistribute it and/or
 * modify it under the terms of the GNU General Public License
 * as published by the Free Software Foundation; either version 2
 * of the License, or (at your option) any later version.
 * 
 * HELM is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with HELM; if not, write to the Free Software
 * Foundation, Inc., 59 Temple Place - Suite 330, Boston,
 * MA  02111-1307, USA.
 * 
 * For details, see the HELM World-Wide-Web page,
 * http://helm.cs.unibo.it/
 *)

(**************************************************************************)
(*                                                                        *)
(*                           PROJECT HELM                                 *)
(*                                                                        *)
(*                Andrea Asperti <asperti@cs.unibo.it>                    *)
(*                             18/2/2004                                  *)
(*                                                                        *)
(**************************************************************************)


open Ast2pres
open TacticAst

let rec count_tactic current_size tac =
  if current_size > maxsize then current_size 
  else match tac with 
    | Absurd (_, term) -> countterm (current_size + 6) term
    | Apply (_, term) -> countterm (current_size + 6) term
    | Auto _ -> current_size + 4
    | Assumption _ -> current_size + 10
    | Change (_, t1, t2, where) ->
        let size1 = countterm (current_size + 12) t1 in (* change, with *)
        let size2 = countterm size1 t2 in
        (match where with 
             None -> size2
           | Some ident -> size2 + 3 + String.length ident)
    | Change_pattern _ -> assert false  (* TODO *)
    | Contradiction _ -> current_size + 13
    | Cut (_, term) -> countterm (current_size + 4) term
    | Decompose (_, ident, principles) ->
        List.fold_left
          (fun size s -> size + (String.length s))
          (current_size + 11 + String.length ident) principles
    | Discriminate (_, ident) -> current_size + 12 + (String.length ident)
    | Elim (_, term, using) ->
        let size1 = countterm (current_size + 5) term in
          (match using with 
           None -> size1
             | Some term -> countterm (size1 + 7) term)
    | ElimType (_, term) -> countterm (current_size + 10) term
    | Exact (_, term) -> countterm (current_size + 6) term
    | Exists _ -> current_size + 6
    | Fold (_, kind, term) ->
        countterm (current_size + 5) term
    | Fourier _ -> current_size + 7
    | Goal (_, n) -> current_size + 4 + int_of_float (ceil (log10 (float n)))
    | Injection (_, ident) -> current_size + 10 + (String.length ident)
    | Intros (_, num, idents) ->
        List.fold_left 
          (fun size s -> size + (String.length s))
          (current_size + 7) idents
    | Left _ -> current_size + 4
    | LetIn (_, term, ident) ->
        countterm (current_size + 5 + String.length ident) term
    | Reduce _ -> assert false  (* TODO *)
    | Reflexivity _ -> current_size + 11
    | Replace (_, t1, t2) -> 
        let size1 = countterm (current_size + 14) t1 in (* replace, with *)
          countterm size1 t2    
    | Replace_pattern _ -> assert false  (* TODO *)
    | Rewrite _ -> assert false (* TODO *)
    | Right _ -> current_size + 5
    | Ring _ -> current_size + 4
    | Split _ -> current_size + 5
    | Symmetry _ -> current_size + 8
    | Transitivity (_, term) -> 
        countterm (current_size + 13) term
;;

let is_big_tac tac =
  let n = (count_tactic 0 tac) in
(*   prerr_endline ("Lunghezza: " ^ (string_of_int n)); *)
  n > maxsize
;;

(* prova *)
let rec small_tactic2box tac =
  Box.Text([], TacticAstPp.pp_tactic tac)

let string_of_kind = function
  | `Reduce -> "reduce"
  | `Simpl -> "simplify"
  | `Whd -> "whd"

let dummy_tbl = Hashtbl.create 0

let ast2astBox ast = Ast2pres.ast2astBox (ast, dummy_tbl)

let pretty_append l ast =
  if is_big ast then
    [Box.H([],l);
     Box.H([],[Box.skip; ast2astBox ast])]
  else
    [Box.H([],l@[Box.smallskip; ast2astBox ast])]

let rec tactic2box tac =
  if (is_big_tac tac) then
    big_tactic2box tac
  else 
    small_tactic2box tac

and big_tactic2box = function
  | Absurd (_, term) ->
      Box.V([],[Box.Text([],"absurd");
                ast2astBox term])
  | Apply (_, term) -> 
      Box.V([],[Box.Text([],"apply");
                ast2astBox term])
  | Assumption _ -> Box.Text([],"assumption")
  | Auto _ -> Box.Text([],"auto")
  | Change (_, t1, t2, where) ->
      let where =
        (match where with 
             None -> []
           | Some ident -> 
               [Box.Text([],"in");
                Box.smallskip;
                Box.Text([],ident)]) in
        Box.V([],
              (pretty_append 
                 [Box.Text([],"change")]
                 t1)@
              (pretty_append 
                 [Box.Text([],"with")]
                 t2)@where)
  | Change_pattern _ -> assert false  (* TODO *)
  | Contradiction _ -> Box.Text([],"contradiction")
  | Cut (_, term) -> 
      Box.V([],[Box.Text([],"cut");
                Box.indent(ast2astBox term)])
  | Decompose (_, ident, principles) ->
      let principles =
        List.map (fun x -> Box.Text([],x)) principles in
      Box.V([],[Box.Text([],"decompose");
                Box.H([],[Box.Text([],"[");
                          Box.V([],principles);
                          Box.Text([],"]")]);
                Box.Text([],ident)])
  | Discriminate (_, ident) -> 
      Box.V([],[Box.Text([],"discriminate");
                Box.Text([],ident)])
  | Elim (_, term, using) ->
      let using =
        (match using with 
             None -> []
           | Some term -> 
               (pretty_append
                  [Box.Text([],"using")]
                  term)) in
      Box.V([],
            (pretty_append
               [Box.Text([],"elim")]
               term)@using)
  | ElimType (_, term) -> 
      Box.V([],[Box.Text([],"elim type");
                Box.indent(ast2astBox term)])
  | Exact (_, term) -> 
      Box.V([],[Box.Text([],"exact");
                Box.indent(ast2astBox term)])
  | Exists _ -> Box.Text([],"exists")
  | Fold (_, kind, term) ->
      Box.V([],[Box.H([],[Box.Text([],"fold");
                          Box.smallskip;
                          Box.Text([],string_of_kind kind)]);
                Box.indent(ast2astBox term)])
  | Fourier _ -> Box.Text([],"fourier")
  | Goal (_, n) -> Box.Text([],"goal " ^ string_of_int n)
  | Injection (_, ident) -> 
      Box.V([],[Box.Text([],"transitivity");
                Box.indent (Box.Text([],ident))])
  | Intros (_, num, idents) ->
      let num =
        (match num with 
             None -> [] 
           | Some num -> [Box.Text([],string_of_int num)]) in
      let idents =
        List.map (fun x -> Box.Text([],x)) idents in
      Box.V([],[Box.Text([],"decompose");
                Box.H([],[Box.smallskip;
                          Box.V([],idents)])])
  | Left _ -> Box.Text([],"left")
  | LetIn (_, term, ident) ->
      Box.V([],[Box.H([],[Box.Text([],"let");
                          Box.smallskip;
                          Box.Text([],ident);
                          Box.smallskip;
                          Box.Text([],"=")]);
                Box.indent (ast2astBox term)])
  | Reduce _ -> assert false  (* TODO *)
  | Reflexivity _ -> Box.Text([],"reflexivity")
  | Replace (_, t1, t2) -> 
      Box.V([],
            (pretty_append 
               [Box.Text([],"replace")]
               t1)@
            (pretty_append 
               [Box.Text([],"with")]
               t2))
  | Replace_pattern _ -> assert false  (* TODO *)
  | Rewrite _ -> assert false (* TODO *)
  | Right _ -> Box.Text([],"right")
  | Ring _ ->  Box.Text([],"ring")
  | Split _ -> Box.Text([],"split")
  | Symmetry _ -> Box.Text([],"symmetry")
  | Transitivity (_, term) -> 
      Box.V([],[Box.Text([],"transitivity");
                Box.indent (ast2astBox term)])
;;

open TacticAst

let rec tactical2box = function
  | Tactic (_, tac) -> tactic2box tac
(*
  | Command cmd -> (* TODO dummy implementation *)
      Box.Text([], TacticAstPp.pp_tactical (Command cmd))
*)

  | Fail _ -> Box.Text([],"fail")
  | Do (_, count, tac) -> 
      Box.V([],[Box.Text([],"do " ^ string_of_int count);
                Box.indent (tactical2box tac)])
  | IdTac _ -> Box.Text([],"id")
  | Repeat (_, tac) -> 
      Box.V([],[Box.Text([],"repeat");
                Box.indent (tactical2box tac)])
  | Seq (_, tacs) -> 
      Box.V([],tacticals2box tacs)
  | Then (_, tac, tacs) -> 
      Box.V([],[tactical2box tac;
                Box.H([],[Box.skip;
                          Box.Text([],"[");
                          Box.V([],tacticals2box tacs);
                          Box.Text([],"]");])])
  | Tries (_, tacs) -> 
      Box.V([],[Box.Text([],"try");
                Box.H([],[Box.skip;
                          Box.Text([],"[");
                          Box.V([],tacticals2box tacs);
                          Box.Text([],"]");])])
  | Try (_, tac) -> 
      Box.V([],[Box.Text([],"try");
                Box.indent (tactical2box tac)])

and tacticals2box tacs =
  List.map 
    (function tac -> Box.H([],[tactical2box tac; Box.Text([],";")])) tacs
;;

let tacticalPp tac =
  String.concat "\n" 
    (BoxPp.to_string CicAstPp.pp_term (tactical2box tac));;