wneuper/isa: src/Tools/isac/Interpret/solve-step.sml@ff2da703f546

     1 (* Title:  Specify/solve-step.sml

     2    Author: Walther Neuper

     3    (c) due to copyright terms

     5 Code for the solve-phase in analogy to structure Specify_Step for the specify-phase.

     6 *)

     8 signature SOLVE_STEP =

     9 sig

    10   val check: Tactic.input -> Calc.T -> Applicable.T

    11   val add: Tactic.T -> Istate_Def.T * Proof.context -> Calc.T -> Test_Out.T

    13   val add_general: Tactic.T -> Istate_Def.T * Proof.context -> Calc.T -> Test_Out.T

    14   val s_add_general: State_Steps.T ->

    15     Ctree.ctree * Pos.pos' list * Pos.pos' -> Ctree.ctree * Pos.pos' list * Pos.pos'

    16   val add_hard:

    17     theory -> Tactic.T -> Pos.pos' -> Ctree.ctree -> Test_Out.T

    19   val get_ruleset: 'a -> Pos.pos -> Ctree.ctree ->

    20     string * ThyC.id * Rewrite_Ord.id * Rule_Def.rule_set * bool

    21   val get_eval: string -> Pos.pos ->Ctree.ctree ->

    22     string * ThyC.id * (string * Rule_Def.eval_fn)

    23 \<^isac_test>\<open>

    24   val rew_info: Rule_Def.rule_set -> string * Rule_Def.rule_set * Rule_Def.calc list

    25 \<close>

    26 end

    28 (**)

    29 structure Solve_Step(**): SOLVE_STEP(**) =

    30 struct

    31 (**)

    33 (** get data from Calc.T **)

    35 (* the source is the parent node, either a problem or a Rule_Set (with inter_steps) *)

    36 fun rew_info (Rule_Def.Repeat {erls, rew_ord = (rew_ord', _), calc = ca, ...}) =

    37     (rew_ord', erls, ca)

    38   | rew_info (Rule_Set.Sequence {erls, rew_ord = (rew_ord', _), calc = ca, ...}) =

    39     (rew_ord', erls, ca)

    40   | rew_info (Rule_Set.Rrls {erls, rew_ord = (rew_ord', _), calc = ca, ...}) =

    41     (rew_ord', erls, ca)

    42   | rew_info rls = raise ERROR ("rew_info called with '" ^ Rule_Set.id rls ^ "'");

    44 fun get_ruleset _ p pt =

    45   let

    46     val (pbl, p', rls') = Ctree.parent_node pt p

    47   in

    48     if pbl

    49     then

    50       let

    51         val thy' = Ctree.get_obj Ctree.g_domID pt p'

    52         val {rew_ord', erls, ...} = MethodC.from_store (Ctree.get_obj Ctree.g_metID pt p')

    53 	    in ("OK", thy', rew_ord', erls, false) end

    54      else

    55       let

    56         val thy' = Ctree.get_obj Ctree.g_domID pt (Ctree.par_pblobj pt p)

    57 		    val (rew_ord', erls, _) = rew_info rls'

    58 		  in ("OK", thy', rew_ord', erls, false) end

    59   end;

    61 fun get_eval scrop p pt =

    62   let

    63     val (pbl, p', rls') =  Ctree.parent_node pt p

    64   in

    65     if pbl

    66     then

    67       let

    68         val thy' = Ctree.get_obj Ctree.g_domID pt p'

    69         val {calc = scr_isa_fns, ...} = MethodC.from_store (Ctree.get_obj Ctree.g_metID pt p')

    70         val opt = assoc (scr_isa_fns, scrop)

    71 	    in

    72 	      case opt of

    73 	        SOME isa_fn => ("OK", thy', isa_fn)

    74 	      | NONE => ("applicable_in Calculate: unknown '" ^ scrop ^ "'", "", ("", Eval_Def.e_evalfn))

    75 	    end

    76     else

    77 		  let

    78 		    val thy' = Ctree.get_obj Ctree.g_domID pt (Ctree.par_pblobj pt p);

    79 		    val (_, _,(*_,*)scr_isa_fns) = rew_info rls'(*rls*)

    80 		  in

    81 		    case assoc (scr_isa_fns, scrop) of

    82 		      SOME isa_fn => ("OK",thy',isa_fn)

    83 		    | NONE => ("applicable_in Calculate: unknown '" ^ scrop ^ "'", "", ("", Eval_Def.e_evalfn))

    84 		  end

    85   end;

    87 (** Solve_Step.check **)

    89 (*

    90   check tactics (input by the user, mostly) for applicability

    91   and determine as much of the result of the tactic as possible initially.

    92 *)

    93 fun check (Tactic.Apply_Method mI) (pt, (p, _)) =

    94       let

    95         val (dI, pI, probl, ctxt) = case Ctree.get_obj I pt p of

    96           Ctree.PblObj {origin = (_, (dI, pI, _), _), probl, ctxt, ...} => (dI, pI, probl, ctxt)

    97         | _ => raise ERROR "Specify_Step.check Apply_Method: uncovered case Ctree.get_obj"

    98         val {where_, ...} = Problem.from_store pI

    99         val pres = map (I_Model.environment probl |> subst_atomic) where_

   100         val ctxt = if ContextC.is_empty ctxt (*vvvvvvvvvvvvvv DO THAT EARLIER?!?*)

   101           then ThyC.get_theory dI |> Proof_Context.init_global |> ContextC.insert_assumptions pres

   102           else ctxt

   103       in

   104         Applicable.Yes (Tactic.Apply_Method' (mI, NONE, Istate_Def.empty (*filled later*), ctxt))

   105       end

   106   | check (Tactic.Calculate op_) (cs as (pt, (p, _))) =

   107       let

   108         val (msg, thy', isa_fn) = get_eval op_ p pt;

   109         val f = Calc.current_formula cs;

   110       in

   111         if msg = "OK"

   112         then

   113     	    case Rewrite.calculate_ (ThyC.id_to_ctxt thy') isa_fn f of

   114     	      SOME (f', (id, thm))

   115     	        => Applicable.Yes (Tactic.Calculate' (thy', op_, f, (f', (id, thm))))

   116     	    | NONE => Applicable.No ("'calculate " ^ op_ ^ "' not applicable")

   117         else Applicable.No msg

   118       end

   119   | check (Tactic.Check_Postcond pI) (_, _) = (*TODO: only applicable, if evaluating to True*)

   120       Applicable.Yes (Tactic.Check_Postcond' (pI, TermC.empty))

   121   | check (Tactic.Check_elementwise pred) cs =

   122       let

   123         val f = Calc.current_formula cs;

   124       in

   125         Applicable.Yes (Tactic.Check_elementwise' (f, pred, (f, [])))

   126       end

   127   | check Tactic.Empty_Tac _ = Applicable.No "Empty_Tac is not applicable"

   128   | check (Tactic.Free_Solve) _ = Applicable.Yes (Tactic.Free_Solve')

   129   | check Tactic.Or_to_List cs =

   130        let

   131         val f = Calc.current_formula cs;

   132         val ls = Prog_Expr.or2list f;

   133       in

   134         Applicable.Yes (Tactic.Or_to_List' (f, ls))

   135       end

   136   | check (Tactic.Rewrite thm) (cs as (pt, (p, _))) =

   137       let

   138         val (msg, thy', ro, rls', _) = get_ruleset thm p pt;

   139         val thy = ThyC.get_theory thy';

   140         val ctxt = Proof_Context.init_global thy;

   141         val f = Calc.current_formula cs;

   142       in

   143         if msg = "OK"

   144         then

   145           case Rewrite.rewrite_ ctxt (assoc_rew_ord thy ro) rls' false (snd thm) f of

   146             SOME (f',asm) => Applicable.Yes (Tactic.Rewrite' (thy', ro, rls', false, thm, f, (f', asm)))

   147           | NONE => Applicable.No ((thm |> fst |> quote) ^ " not applicable")

   148         else Applicable.No msg

   149       end

   150   | check (Tactic.Rewrite_Inst (subs, thm)) (cs as (pt, pos as (p, _))) =

   151       let

   152         val pp = Ctree.par_pblobj pt p;

   153 (*ctxt*)

   154         val thy' = Ctree.get_obj Ctree.g_domID pt pp;

   155         val thy = ThyC.get_theory thy';

   156         val ctxt = Proof_Context.init_global thy;

   157 (*ctxt* )

   158 val ctxt = Ctree.get_loc pt pos |> snd

   159 val thy = Proof_Context.theory_of ctxt

   160 val thy' = Context.theory_name thy

   161 ( *ctxt*)

   162         val {rew_ord' = ro', erls = erls, ...} = MethodC.from_store (Ctree.get_obj Ctree.g_metID pt pp);

   163         val f = Calc.current_formula cs;

   164         val subst = Subst.T_from_input ctxt subs; (*TODO: input requires parse _: _ -> _ option*)

   165       in

   166         case Rewrite.rewrite_inst_ ctxt (assoc_rew_ord thy ro') erls false subst (snd thm) f of

   167           SOME (f', asm) =>

   168             Applicable.Yes (Tactic.Rewrite_Inst' (thy', ro', erls, false, subst, thm, f, (f', asm)))

   169         | NONE => Applicable.No (fst thm ^ " not applicable")

   170       end

   171   | check (Tactic.Rewrite_Set rls) (cs as (pt, pos as (p, _))) =

   172       let

   173 (*ctxt*)

   174         val pp = Ctree.par_pblobj pt p;

   175         val thy' = Ctree.get_obj Ctree.g_domID pt pp;

   176 (*ctxt* )

   177 val ctxt = Ctree.get_loc pt pos |> snd

   178 val thy = Proof_Context.theory_of ctxt

   179 val thy' = Context.theory_name thy

   180 ( *ctxt*)

   181         val f = Calc.current_formula cs;

   182       in

   183         case Rewrite.rewrite_set_ (ThyC.id_to_ctxt thy') false (assoc_rls rls) f of

   184           SOME (f', asm)

   185             => Applicable.Yes (Tactic.Rewrite_Set' (thy', false, assoc_rls rls, f, (f', asm)))

   186           | NONE => Applicable.No (rls ^ " not applicable")

   187       end

   188   | check (Tactic.Rewrite_Set_Inst (subs, rls)) (cs as (pt, pos as (p, _))) =

   189       let

   190 (*ctxt*)

   191         val pp = Ctree.par_pblobj pt p;

   192         val thy' = Ctree.get_obj Ctree.g_domID pt pp;

   193         val thy = ThyC.get_theory thy';

   194         val ctxt = Proof_Context.init_global thy;

   195 (*ctxt* )

   196 val ctxt = Ctree.get_loc pt pos |> snd

   197 val thy = Proof_Context.theory_of ctxt

   198 val thy' = Context.theory_name thy

   199 ( *ctxt*)

   200         val f = Calc.current_formula cs;

   201     	  val subst = Subst.T_from_input ctxt subs; (*TODO: input requires parse _: _ -> _ option*)

   202       in

   203         case Rewrite.rewrite_set_inst_ ctxt false subst (assoc_rls rls) f of

   204           SOME (f', asm)

   205             => Applicable.Yes (Tactic.Rewrite_Set_Inst' (thy', false, subst, assoc_rls rls, f, (f', asm)))

   206         | NONE => Applicable.No (rls ^ " not applicable")

   207       end

   208   | check (Tactic.Subproblem (domID, pblID)) (_, _) =

   209       Applicable.Yes (Tactic.Subproblem' ((domID, pblID, MethodC.id_empty), [],

   210 			  TermC.empty, [], ContextC.empty, Auto_Prog.subpbl domID pblID))

   211   | check (Tactic.Substitute sube) (cs as (pt, pos as (p, _))) =

   212       let

   213         val pp = Ctree.par_pblobj pt p

   214 (*ctxt*)

   215         val thy = ThyC.get_theory (Ctree.get_obj Ctree.g_domID pt pp)

   216         val ctxt = Proof_Context.init_global thy;

   217 (*ctxt* )

   218 val ctxt = Ctree.get_loc pt pos |> snd

   219 val thy = Proof_Context.theory_of ctxt

   220 val thy' = Context.theory_name thy

   221 ( *ctxt*)

   222         val f = Calc.current_formula cs;

   223 		    val {rew_ord', erls, ...} = MethodC.from_store (Ctree.get_obj Ctree.g_metID pt pp)

   224 		    val subte = Subst.input_to_terms sube (*TODO: input requires parse _: _ -> _ option*)

   225 		    val subst = Subst.T_from_string_eqs thy sube

   226 		    val ro = assoc_rew_ord thy rew_ord'

   227 		  in

   228 		    if foldl and_ (true, map TermC.contains_Var subte)

   229 		    then (*1*)

   230 		      let val f' = subst_atomic subst f

   231 		      in if f = f'

   232 		        then Applicable.No (Subst.string_eqs_to_string sube ^ " not applicable")

   233 		        else Applicable.Yes (Tactic.Substitute' (ro, erls, subte, f, f'))

   234 		      end

   235 		    else (*2*)

   236 		      case Rewrite.rewrite_terms_ ctxt ro erls subte f of

   237 		        SOME (f', _) =>  Applicable.Yes (Tactic.Substitute' (ro, erls, subte, f, f'))

   238 		      | NONE => Applicable.No (Subst.string_eqs_to_string sube ^ " not applicable")

   239 		  end

   240   | check (Tactic.Tac id) (cs as (pt, (p, _))) =

   241       let

   242 (*ctxt*)

   243         val pp = Ctree.par_pblobj pt p;

   244         val thy' = Ctree.get_obj Ctree.g_domID pt pp;

   245         val thy = ThyC.get_theory thy';

   246 (*ctxt* )

   247 val ctxt = Ctree.get_loc pt pos |> snd

   248 val thy = Proof_Context.theory_of ctxt

   249 val thy' = Context.theory_name thy

   250 ( *ctxt*)

   251         val f = Calc.current_formula cs;

   252       in

   253         Applicable.Yes (Tactic.Tac_ (thy, UnparseC.term f, id, UnparseC.term f))

   254       end

   255   | check (Tactic.Take str) _ = Applicable.Yes (Tactic.Take' (TermC.str2term str)) (* always applicable ?*)

   256   | check (Tactic.Begin_Trans) cs =

   257       Applicable.Yes (Tactic.Begin_Trans' (Calc.current_formula cs))

   258   | check (Tactic.End_Trans) (pt, (p, p_)) = (*TODO: check parent branches*)

   259     if p_ = Pos.Res

   260 	  then Applicable.Yes (Tactic.End_Trans' (Ctree.get_obj Ctree.g_result pt p))

   261     else Applicable.No "'End_Trans' is not applicable at the beginning of a transitive sequence"

   262   | check Tactic.End_Proof' _ = Applicable.Yes Tactic.End_Proof''

   263   | check m _ = raise ERROR ("Solve_Step.check called for " ^ Tactic.input_to_string m);

   266 (** Solve_Step.add **)

   268 fun add (Tactic.Apply_Method' (_, topt, is, _)) (_, ctxt) (pt, pos as (p, _)) =

   269     (case topt of

   270       SOME t =>

   271         let val (pt, c) = Ctree.cappend_form pt p (is, ctxt) t

   272         in (pos, c, Test_Out.EmptyMout, pt) end

   273     | NONE => (pos, [], Test_Out.EmptyMout, pt))

   274   | add (Tactic.Take' t) l (pt, (p, _)) = (* val (Take' t) = m; *)

   275     let

   276       val p =

   277         let val (ps, p') = split_last p (* no connex to prev.ppobj *)

   278 	      in if p' = 0 then ps @ [1] else p end

   279       val (pt, c) = Ctree.cappend_form pt p l t

   280     in

   281       ((p, Pos.Frm), c, Test_Out.FormKF (UnparseC.term t), pt)

   282     end

   283   | add (Tactic.Begin_Trans' t) l (pt, (p, Pos.Frm)) =

   284     let

   285       val (pt, c) = Ctree.cappend_form pt p l t

   286       val pt = Ctree.update_branch pt p Ctree.TransitiveB (*040312*)

   287       (* replace the old PrfOjb ~~~~~ *)

   288       val p = (Pos.lev_on o Pos.lev_dn (* starts with [...,0] *)) p

   289       val (pt, c') = Ctree.cappend_form pt p l t (*FIXME.0402 same istate ???*)

   290     in

   291       ((p, Pos.Frm), c @ c', Test_Out.FormKF (UnparseC.term t), pt)

   292     end

   293   | add (Tactic.Begin_Trans' t) l (pt, (p, Pos.Res)) =

   294     (*append after existing PrfObj    vvvvvvvvvvvvv*)

   295     add (Tactic.Begin_Trans' t) l (pt, (Pos.lev_on p, Pos.Frm))

   296   | add (Tactic.End_Trans' tasm) l (pt, (p, _)) =

   297     let

   298       val p' = Pos.lev_up p

   299       val (pt, c) = Ctree.append_result pt p' l tasm Ctree.Complete

   300     in

   301       ((p', Pos.Res), c, Test_Out.FormKF "DUMMY" (*term2str t ..ERROR (t) has not been declared*), pt)

   302     end

   303   | add (Tactic.Rewrite_Inst' (_, _, _, _, subs', thm', f, (f', asm))) (is, ctxt) (pt, (p, _)) =

   304     let

   305       val (pt, c) = Ctree.cappend_atomic pt p (is, ctxt) f

   306         (Tactic.Rewrite_Inst (Subst.T_to_input subs', thm')) (f',asm) Ctree.Complete;

   307       val pt = Ctree.update_branch pt p Ctree.TransitiveB

   308     in

   309       ((p, Pos.Res), c, Test_Out.FormKF (UnparseC.term f'), pt)

   310     end

   311  | add (Tactic.Rewrite' (_, _, _, _, thm', f, (f', asm))) (is, ctxt) (pt, (p, _)) =

   312    let

   313      val (pt, c) = Ctree.cappend_atomic pt p (is, ctxt) f (Tactic.Rewrite thm') (f', asm) Ctree.Complete

   314      val pt = Ctree.update_branch pt p Ctree.TransitiveB

   315    in

   316     ((p, Pos.Res), c, Test_Out.FormKF (UnparseC.term f'), pt)

   317    end

   318   | add (Tactic.Rewrite_Set_Inst' (_, _, subs', rls', f, (f', asm))) (is, ctxt) (pt, (p, _)) =

   319     let

   320       val (pt, c) = Ctree.cappend_atomic pt p (is, ctxt) f

   321         (Tactic.Rewrite_Set_Inst (Subst.T_to_input subs', Rule_Set.id rls')) (f', asm) Ctree.Complete

   322       val pt = Ctree.update_branch pt p Ctree.TransitiveB

   323     in

   324       ((p, Pos.Res), c, Test_Out.FormKF (UnparseC.term f'), pt)

   325     end

   326   | add (Tactic.Rewrite_Set' (_, _, rls', f, (f', asm))) (is, ctxt) (pt, (p, _)) =

   327     let

   328       val (pt, c) = Ctree.cappend_atomic pt p (is, ctxt) f

   329         (Tactic.Rewrite_Set (Rule_Set.id rls')) (f', asm) Ctree.Complete

   330       val pt = Ctree.update_branch pt p Ctree.TransitiveB

   331     in

   332       ((p, Pos.Res), c, Test_Out.FormKF (UnparseC.term f'), pt)

   333     end

   334   | add (Tactic.Check_Postcond' (_, scval)) l (pt, (p, _)) =

   335       let

   336         val (pt, c) = Ctree.append_result pt p l (scval, []) Ctree.Complete

   337       in

   338         ((p, Pos.Res), c, Test_Out.FormKF (UnparseC.term scval), pt)

   339       end

   340   | add (Tactic.Calculate' (_, op_, f, (f', _))) l (pt, (p, _)) =

   341       let

   342         val (pt,c) = Ctree.cappend_atomic pt p l f (Tactic.Calculate op_) (f', []) Ctree.Complete

   343       in

   344         ((p, Pos.Res), c, Test_Out.FormKF (UnparseC.term f'), pt)

   345       end

   346   | add (Tactic.Check_elementwise' (consts, pred, (f', asm))) l (pt, (p, _)) =

   347       let

   348         val (pt,c) = Ctree.cappend_atomic pt p l consts (Tactic.Check_elementwise pred) (f', asm) Ctree.Complete

   349       in

   350         ((p, Pos.Res), c, Test_Out.FormKF (UnparseC.term f'), pt)

   351       end

   352   | add (Tactic.Or_to_List' (ors, list)) l (pt, (p, _)) =

   353       let

   354         val (pt,c) = Ctree.cappend_atomic pt p l ors Tactic.Or_to_List (list, []) Ctree.Complete

   355       in

   356         ((p, Pos.Res), c, Test_Out.FormKF (UnparseC.term list), pt)

   357       end

   358   | add (Tactic.Substitute' (_, _, subte, t, t')) l (pt, (p, _)) =

   359       let

   360         val (pt,c) =

   361           Ctree.cappend_atomic pt p l t (Tactic.Substitute (Subst.eqs_to_input subte)) (t',[]) Ctree.Complete

   362         in ((p, Pos.Res), c, Test_Out.FormKF (UnparseC.term t'), pt)

   363         end

   364   | add (Tactic.Tac_ (_, f, id, f')) l (pt, (p, _)) =

   365       let

   366         val (pt, c) = Ctree.cappend_atomic pt p l (TermC.str2term f) (Tactic.Tac id) (TermC.str2term f', []) Ctree.Complete

   367       in

   368         ((p,Pos.Res), c, Test_Out.FormKF f', pt)

   369       end

   370   | add (Tactic.Subproblem' ((domID, pblID, metID), oris, hdl, fmz_, ctxt_specify, f))

   371       (l as (_, ctxt)) (pt, (p, _)) =

   372       let

   373   	    val (pt, c) = Ctree.cappend_problem pt p l (fmz_, (domID, pblID, metID))

   374   	      (oris, (domID, pblID, metID), hdl, ctxt_specify)

   375   	    val f = Syntax.string_of_term ctxt f

   376       in

   377         ((p, Pos.Pbl), c, Test_Out.FormKF f, pt)

   378       end

   379   | add m' _ (_, pos) =

   380       raise ERROR ("Solve_Step.add: not impl.for " ^ Tactic.string_of m' ^ " at " ^ Pos.pos'2str pos)

   382 (* LI switches between solve-phase and specify-phase *)

   383 fun add_general tac ic cs =

   384   if Tactic.for_specify' tac

   385   then Specify_Step.add tac ic cs

   386   else add tac ic cs

   388 (* the order of State_Steps is reversed: insert last element first  *)

   389 fun s_add_general [] ptp = ptp

   390   | s_add_general tacis (pt, c, _) =

   391     let

   392       val (tacis', (_, tac_, (p, is))) = split_last tacis

   393 	    val (p', c', _, pt') = add_general tac_ is (pt, p)

   394     in

   395       s_add_general tacis' (pt', c@c', p')

   396     end

   398 (* a still undeveloped concept: do a calculation without LI *)

   399 fun add_hard _(*thy*) m' (p, p_) pt =

   400   let

   401     val p = case p_ of

   402       Pos.Frm => p | Pos.Res => Pos.lev_on p

   403     | _ => raise ERROR ("generate_hard: call by " ^ Pos.pos'2str (p,p_))

   404   in

   405     add_general m' (Istate_Def.empty, ContextC.empty) (pt, (p, p_))

   406   end

   408 (**)end(**);

author	wneuper <Walther.Neuper@jku.at>
	Tue, 16 Aug 2022 12:21:21 +0200
changeset 60527	ff2da703f546
parent 60509	2e0b7ca391dc
child 60530	edb91d2a28c1
permissions	-rw-r--r--