src/HOL/Tools/Groebner_Basis/normalizer.ML
author haftmann
Wed Nov 28 09:01:34 2007 +0100 (2007-11-28)
changeset 25481 aa16cd919dcc
parent 25253 c642b36f2bec
child 27222 b08abdb8f499
permissions -rw-r--r--
dropped legacy ml bindings
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(*  Title:      HOL/Tools/Groebner_Basis/normalizer.ML
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    ID:         $Id$
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    Author:     Amine Chaieb, TU Muenchen
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*)
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signature NORMALIZER = 
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sig
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 val semiring_normalize_conv : Proof.context -> conv
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 val semiring_normalize_ord_conv : Proof.context -> (cterm -> cterm -> bool) -> conv
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 val semiring_normalize_tac : Proof.context -> int -> tactic
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 val semiring_normalize_wrapper :  Proof.context -> NormalizerData.entry -> conv
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 val semiring_normalize_ord_wrapper :  Proof.context -> NormalizerData.entry ->
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   (cterm -> cterm -> bool) -> conv
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 val semiring_normalizers_conv :
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     cterm list -> cterm list * thm list -> cterm list * thm list ->
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     (cterm -> bool) * conv * conv * conv -> (cterm -> cterm -> bool) ->
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       {add: conv, mul: conv, neg: conv, main: conv, pow: conv, sub: conv}
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end
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structure Normalizer: NORMALIZER = 
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struct
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open Conv;
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(* Very basic stuff for terms *)
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fun is_comb ct =
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  (case Thm.term_of ct of
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    _ $ _ => true
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  | _ => false);
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val concl = Thm.cprop_of #> Thm.dest_arg;
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fun is_binop ct ct' =
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  (case Thm.term_of ct' of
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    c $ _ $ _ => term_of ct aconv c
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  | _ => false);
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fun dest_binop ct ct' =
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  if is_binop ct ct' then Thm.dest_binop ct'
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  else raise CTERM ("dest_binop: bad binop", [ct, ct'])
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fun inst_thm inst = Thm.instantiate ([], inst);
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val dest_numeral = term_of #> HOLogic.dest_number #> snd;
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val is_numeral = can dest_numeral;
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val numeral01_conv = Simplifier.rewrite
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                         (HOL_basic_ss addsimps [@{thm numeral_1_eq_1}, @{thm numeral_0_eq_0}]);
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val zero1_numeral_conv = 
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 Simplifier.rewrite (HOL_basic_ss addsimps [@{thm numeral_1_eq_1} RS sym, @{thm numeral_0_eq_0} RS sym]);
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fun zerone_conv cv = zero1_numeral_conv then_conv cv then_conv numeral01_conv;
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val natarith = [@{thm "add_nat_number_of"}, @{thm "diff_nat_number_of"},
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                @{thm "mult_nat_number_of"}, @{thm "eq_nat_number_of"}, 
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                @{thm "less_nat_number_of"}];
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val nat_add_conv = 
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 zerone_conv 
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  (Simplifier.rewrite 
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    (HOL_basic_ss 
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       addsimps @{thms arith_simps} @ natarith @ @{thms rel_simps}
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             @ [if_False, if_True, @{thm add_0}, @{thm add_Suc},
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                 @{thm add_number_of_left}, @{thm Suc_eq_add_numeral_1}]
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             @ map (fn th => th RS sym) @{thms numerals}));
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val nat_mul_conv = nat_add_conv;
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val zeron_tm = @{cterm "0::nat"};
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val onen_tm  = @{cterm "1::nat"};
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val true_tm = @{cterm "True"};
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(* The main function! *)
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fun semiring_normalizers_conv vars (sr_ops, sr_rules) (r_ops, r_rules)
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  (is_semiring_constant, semiring_add_conv, semiring_mul_conv, semiring_pow_conv) =
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let
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val [pthm_02, pthm_03, pthm_04, pthm_05, pthm_07, pthm_08,
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     pthm_09, pthm_10, pthm_11, pthm_12, pthm_13, pthm_14, pthm_15, pthm_16,
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     pthm_17, pthm_18, pthm_19, pthm_21, pthm_22, pthm_23, pthm_24,
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     pthm_25, pthm_26, pthm_27, pthm_28, pthm_29, pthm_30, pthm_31, pthm_32,
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     pthm_33, pthm_34, pthm_35, pthm_36, pthm_37, pthm_38,pthm_39,pthm_40] = sr_rules;
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val [ca, cb, cc, cd, cm, cn, cp, cq, cx, cy, cz, clx, crx, cly, cry] = vars;
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val [add_pat, mul_pat, pow_pat, zero_tm, one_tm] = sr_ops;
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val [add_tm, mul_tm, pow_tm] = map (Thm.dest_fun o Thm.dest_fun) [add_pat, mul_pat, pow_pat];
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val dest_add = dest_binop add_tm
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val dest_mul = dest_binop mul_tm
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fun dest_pow tm =
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 let val (l,r) = dest_binop pow_tm tm
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 in if is_numeral r then (l,r) else raise CTERM ("dest_pow",[tm])
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 end;
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val is_add = is_binop add_tm
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val is_mul = is_binop mul_tm
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fun is_pow tm = is_binop pow_tm tm andalso is_numeral(Thm.dest_arg tm);
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val (neg_mul,sub_add,sub_tm,neg_tm,dest_sub,is_sub,cx',cy') =
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  (case (r_ops, r_rules) of
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    ([], []) => (TrueI, TrueI, true_tm, true_tm, (fn t => (t,t)), K false, true_tm, true_tm)
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  | ([sub_pat, neg_pat], [neg_mul, sub_add]) =>
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      let
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        val sub_tm = Thm.dest_fun (Thm.dest_fun sub_pat)
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        val neg_tm = Thm.dest_fun neg_pat
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        val dest_sub = dest_binop sub_tm
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        val is_sub = is_binop sub_tm
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      in (neg_mul,sub_add,sub_tm,neg_tm,dest_sub,is_sub, neg_mul |> concl |> Thm.dest_arg,
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          sub_add |> concl |> Thm.dest_arg |> Thm.dest_arg)
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      end);
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in fn variable_order =>
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 let
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(* Conversion for "x^n * x^m", with either x^n = x and/or x^m = x possible.  *)
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(* Also deals with "const * const", but both terms must involve powers of    *)
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(* the same variable, or both be constants, or behaviour may be incorrect.   *)
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 fun powvar_mul_conv tm =
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  let
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  val (l,r) = dest_mul tm
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  in if is_semiring_constant l andalso is_semiring_constant r
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     then semiring_mul_conv tm
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     else
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      ((let
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         val (lx,ln) = dest_pow l
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        in
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         ((let val (rx,rn) = dest_pow r
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               val th1 = inst_thm [(cx,lx),(cp,ln),(cq,rn)] pthm_29
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                val (tm1,tm2) = Thm.dest_comb(concl th1) in
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               transitive th1 (Drule.arg_cong_rule tm1 (nat_add_conv tm2)) end)
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           handle CTERM _ =>
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            (let val th1 = inst_thm [(cx,lx),(cq,ln)] pthm_31
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                 val (tm1,tm2) = Thm.dest_comb(concl th1) in
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               transitive th1 (Drule.arg_cong_rule tm1 (nat_add_conv tm2)) end)) end)
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       handle CTERM _ =>
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           ((let val (rx,rn) = dest_pow r
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                val th1 = inst_thm [(cx,rx),(cq,rn)] pthm_30
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                val (tm1,tm2) = Thm.dest_comb(concl th1) in
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               transitive th1 (Drule.arg_cong_rule tm1 (nat_add_conv tm2)) end)
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           handle CTERM _ => inst_thm [(cx,l)] pthm_32
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))
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 end;
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(* Remove "1 * m" from a monomial, and just leave m.                         *)
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 fun monomial_deone th =
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       (let val (l,r) = dest_mul(concl th) in
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           if l aconvc one_tm
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          then transitive th (inst_thm [(ca,r)] pthm_13)  else th end)
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       handle CTERM _ => th;
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(* Conversion for "(monomial)^n", where n is a numeral.                      *)
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 val monomial_pow_conv =
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  let
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   fun monomial_pow tm bod ntm =
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    if not(is_comb bod)
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    then reflexive tm
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    else
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     if is_semiring_constant bod
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     then semiring_pow_conv tm
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     else
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      let
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      val (lopr,r) = Thm.dest_comb bod
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      in if not(is_comb lopr)
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         then reflexive tm
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        else
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          let
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          val (opr,l) = Thm.dest_comb lopr
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         in
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           if opr aconvc pow_tm andalso is_numeral r
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          then
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            let val th1 = inst_thm [(cx,l),(cp,r),(cq,ntm)] pthm_34
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                val (l,r) = Thm.dest_comb(concl th1)
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           in transitive th1 (Drule.arg_cong_rule l (nat_mul_conv r))
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           end
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           else
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            if opr aconvc mul_tm
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            then
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             let
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              val th1 = inst_thm [(cx,l),(cy,r),(cq,ntm)] pthm_33
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             val (xy,z) = Thm.dest_comb(concl th1)
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              val (x,y) = Thm.dest_comb xy
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              val thl = monomial_pow y l ntm
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              val thr = monomial_pow z r ntm
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             in transitive th1 (combination (Drule.arg_cong_rule x thl) thr)
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             end
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             else reflexive tm
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          end
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      end
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  in fn tm =>
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   let
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    val (lopr,r) = Thm.dest_comb tm
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    val (opr,l) = Thm.dest_comb lopr
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   in if not (opr aconvc pow_tm) orelse not(is_numeral r)
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      then raise CTERM ("monomial_pow_conv", [tm])
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      else if r aconvc zeron_tm
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      then inst_thm [(cx,l)] pthm_35
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      else if r aconvc onen_tm
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      then inst_thm [(cx,l)] pthm_36
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      else monomial_deone(monomial_pow tm l r)
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   end
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  end;
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(* Multiplication of canonical monomials.                                    *)
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 val monomial_mul_conv =
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  let
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   fun powvar tm =
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    if is_semiring_constant tm then one_tm
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    else
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     ((let val (lopr,r) = Thm.dest_comb tm
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           val (opr,l) = Thm.dest_comb lopr
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       in if opr aconvc pow_tm andalso is_numeral r then l 
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          else raise CTERM ("monomial_mul_conv",[tm]) end)
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     handle CTERM _ => tm)   (* FIXME !? *)
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   fun  vorder x y =
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    if x aconvc y then 0
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    else
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     if x aconvc one_tm then ~1
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     else if y aconvc one_tm then 1
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      else if variable_order x y then ~1 else 1
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   fun monomial_mul tm l r =
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    ((let val (lx,ly) = dest_mul l val vl = powvar lx
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      in
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      ((let
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        val (rx,ry) = dest_mul r
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         val vr = powvar rx
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         val ord = vorder vl vr
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        in
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         if ord = 0
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        then
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          let
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             val th1 = inst_thm [(clx,lx),(cly,ly),(crx,rx),(cry,ry)] pthm_15
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             val (tm1,tm2) = Thm.dest_comb(concl th1)
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             val (tm3,tm4) = Thm.dest_comb tm1
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             val th2 = Drule.fun_cong_rule (Drule.arg_cong_rule tm3 (powvar_mul_conv tm4)) tm2
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             val th3 = transitive th1 th2
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              val  (tm5,tm6) = Thm.dest_comb(concl th3)
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              val  (tm7,tm8) = Thm.dest_comb tm6
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             val  th4 = monomial_mul tm6 (Thm.dest_arg tm7) tm8
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         in  transitive th3 (Drule.arg_cong_rule tm5 th4)
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         end
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         else
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          let val th0 = if ord < 0 then pthm_16 else pthm_17
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             val th1 = inst_thm [(clx,lx),(cly,ly),(crx,rx),(cry,ry)] th0
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             val (tm1,tm2) = Thm.dest_comb(concl th1)
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             val (tm3,tm4) = Thm.dest_comb tm2
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         in transitive th1 (Drule.arg_cong_rule tm1 (monomial_mul tm2 (Thm.dest_arg tm3) tm4))
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         end
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        end)
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       handle CTERM _ =>
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        (let val vr = powvar r val ord = vorder vl vr
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        in
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          if ord = 0 then
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           let
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           val th1 = inst_thm [(clx,lx),(cly,ly),(crx,r)] pthm_18
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                 val (tm1,tm2) = Thm.dest_comb(concl th1)
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           val (tm3,tm4) = Thm.dest_comb tm1
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           val th2 = Drule.fun_cong_rule (Drule.arg_cong_rule tm3 (powvar_mul_conv tm4)) tm2
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          in transitive th1 th2
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          end
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          else
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          if ord < 0 then
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            let val th1 = inst_thm [(clx,lx),(cly,ly),(crx,r)] pthm_19
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                val (tm1,tm2) = Thm.dest_comb(concl th1)
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                val (tm3,tm4) = Thm.dest_comb tm2
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           in transitive th1 (Drule.arg_cong_rule tm1 (monomial_mul tm2 (Thm.dest_arg tm3) tm4))
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           end
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           else inst_thm [(ca,l),(cb,r)] pthm_09
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        end)) end)
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     handle CTERM _ =>
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      (let val vl = powvar l in
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        ((let
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          val (rx,ry) = dest_mul r
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          val vr = powvar rx
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           val ord = vorder vl vr
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         in if ord = 0 then
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              let val th1 = inst_thm [(clx,l),(crx,rx),(cry,ry)] pthm_21
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                 val (tm1,tm2) = Thm.dest_comb(concl th1)
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                 val (tm3,tm4) = Thm.dest_comb tm1
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             in transitive th1 (Drule.fun_cong_rule (Drule.arg_cong_rule tm3 (powvar_mul_conv tm4)) tm2)
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             end
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             else if ord > 0 then
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                 let val th1 = inst_thm [(clx,l),(crx,rx),(cry,ry)] pthm_22
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                     val (tm1,tm2) = Thm.dest_comb(concl th1)
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                    val (tm3,tm4) = Thm.dest_comb tm2
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                in transitive th1 (Drule.arg_cong_rule tm1 (monomial_mul tm2 (Thm.dest_arg tm3) tm4))
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                end
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             else reflexive tm
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         end)
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        handle CTERM _ =>
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          (let val vr = powvar r
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               val  ord = vorder vl vr
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          in if ord = 0 then powvar_mul_conv tm
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              else if ord > 0 then inst_thm [(ca,l),(cb,r)] pthm_09
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              else reflexive tm
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          end)) end))
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  in fn tm => let val (l,r) = dest_mul tm in monomial_deone(monomial_mul tm l r)
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             end
wenzelm@23252
   298
  end;
wenzelm@23252
   299
(* Multiplication by monomial of a polynomial.                               *)
wenzelm@23252
   300
wenzelm@23252
   301
 val polynomial_monomial_mul_conv =
wenzelm@23252
   302
  let
wenzelm@23252
   303
   fun pmm_conv tm =
wenzelm@23252
   304
    let val (l,r) = dest_mul tm
wenzelm@23252
   305
    in
wenzelm@23252
   306
    ((let val (y,z) = dest_add r
wenzelm@23252
   307
          val th1 = inst_thm [(cx,l),(cy,y),(cz,z)] pthm_37
wenzelm@23252
   308
          val (tm1,tm2) = Thm.dest_comb(concl th1)
wenzelm@23252
   309
          val (tm3,tm4) = Thm.dest_comb tm1
wenzelm@23252
   310
          val th2 = combination (Drule.arg_cong_rule tm3 (monomial_mul_conv tm4)) (pmm_conv tm2)
wenzelm@23252
   311
      in transitive th1 th2
wenzelm@23252
   312
      end)
wenzelm@23252
   313
     handle CTERM _ => monomial_mul_conv tm)
wenzelm@23252
   314
   end
wenzelm@23252
   315
 in pmm_conv
wenzelm@23252
   316
 end;
wenzelm@23252
   317
wenzelm@23252
   318
(* Addition of two monomials identical except for constant multiples.        *)
wenzelm@23252
   319
wenzelm@23252
   320
fun monomial_add_conv tm =
wenzelm@23252
   321
 let val (l,r) = dest_add tm
wenzelm@23252
   322
 in if is_semiring_constant l andalso is_semiring_constant r
wenzelm@23252
   323
    then semiring_add_conv tm
wenzelm@23252
   324
    else
wenzelm@23252
   325
     let val th1 =
wenzelm@23252
   326
           if is_mul l andalso is_semiring_constant(Thm.dest_arg1 l)
wenzelm@23252
   327
           then if is_mul r andalso is_semiring_constant(Thm.dest_arg1 r) then
wenzelm@23252
   328
                    inst_thm [(ca,Thm.dest_arg1 l),(cm,Thm.dest_arg r), (cb,Thm.dest_arg1 r)] pthm_02
wenzelm@23252
   329
                else inst_thm [(ca,Thm.dest_arg1 l),(cm,r)] pthm_03
wenzelm@23252
   330
           else if is_mul r andalso is_semiring_constant(Thm.dest_arg1 r)
wenzelm@23252
   331
           then inst_thm [(cm,l),(ca,Thm.dest_arg1 r)] pthm_04
wenzelm@23252
   332
           else inst_thm [(cm,r)] pthm_05
wenzelm@23252
   333
         val (tm1,tm2) = Thm.dest_comb(concl th1)
wenzelm@23252
   334
         val (tm3,tm4) = Thm.dest_comb tm1
wenzelm@23252
   335
         val th2 = Drule.arg_cong_rule tm3 (semiring_add_conv tm4)
wenzelm@23252
   336
         val th3 = transitive th1 (Drule.fun_cong_rule th2 tm2)
wenzelm@23252
   337
         val tm5 = concl th3
wenzelm@23252
   338
      in
wenzelm@23252
   339
      if (Thm.dest_arg1 tm5) aconvc zero_tm
wenzelm@23252
   340
      then transitive th3 (inst_thm [(ca,Thm.dest_arg tm5)] pthm_11)
wenzelm@23252
   341
      else monomial_deone th3
wenzelm@23252
   342
     end
wenzelm@23252
   343
 end;
wenzelm@23252
   344
wenzelm@23252
   345
(* Ordering on monomials.                                                    *)
wenzelm@23252
   346
wenzelm@23252
   347
fun striplist dest =
wenzelm@23252
   348
 let fun strip x acc =
wenzelm@23252
   349
   ((let val (l,r) = dest x in
wenzelm@23252
   350
        strip l (strip r acc) end)
wenzelm@23252
   351
    handle CTERM _ => x::acc)    (* FIXME !? *)
wenzelm@23252
   352
 in fn x => strip x []
wenzelm@23252
   353
 end;
wenzelm@23252
   354
wenzelm@23252
   355
wenzelm@23252
   356
fun powervars tm =
wenzelm@23252
   357
 let val ptms = striplist dest_mul tm
wenzelm@23252
   358
 in if is_semiring_constant (hd ptms) then tl ptms else ptms
wenzelm@23252
   359
 end;
wenzelm@23252
   360
val num_0 = 0;
wenzelm@23252
   361
val num_1 = 1;
wenzelm@23252
   362
fun dest_varpow tm =
wenzelm@23252
   363
 ((let val (x,n) = dest_pow tm in (x,dest_numeral n) end)
wenzelm@23252
   364
   handle CTERM _ =>
wenzelm@23252
   365
   (tm,(if is_semiring_constant tm then num_0 else num_1)));
wenzelm@23252
   366
wenzelm@23252
   367
val morder =
wenzelm@23252
   368
 let fun lexorder l1 l2 =
wenzelm@23252
   369
  case (l1,l2) of
wenzelm@23252
   370
    ([],[]) => 0
wenzelm@23252
   371
  | (vps,[]) => ~1
wenzelm@23252
   372
  | ([],vps) => 1
wenzelm@23252
   373
  | (((x1,n1)::vs1),((x2,n2)::vs2)) =>
wenzelm@23252
   374
     if variable_order x1 x2 then 1
wenzelm@23252
   375
     else if variable_order x2 x1 then ~1
wenzelm@23252
   376
     else if n1 < n2 then ~1
wenzelm@23252
   377
     else if n2 < n1 then 1
wenzelm@23252
   378
     else lexorder vs1 vs2
wenzelm@23252
   379
 in fn tm1 => fn tm2 =>
wenzelm@23252
   380
  let val vdegs1 = map dest_varpow (powervars tm1)
wenzelm@23252
   381
      val vdegs2 = map dest_varpow (powervars tm2)
wenzelm@23252
   382
      val deg1 = fold_rev ((curry (op +)) o snd) vdegs1 num_0
wenzelm@23252
   383
      val deg2 = fold_rev ((curry (op +)) o snd) vdegs2 num_0
wenzelm@23252
   384
  in if deg1 < deg2 then ~1 else if deg1 > deg2 then 1
wenzelm@23252
   385
                            else lexorder vdegs1 vdegs2
wenzelm@23252
   386
  end
wenzelm@23252
   387
 end;
wenzelm@23252
   388
wenzelm@23252
   389
(* Addition of two polynomials.                                              *)
wenzelm@23252
   390
wenzelm@23252
   391
val polynomial_add_conv =
wenzelm@23252
   392
 let
wenzelm@23252
   393
 fun dezero_rule th =
wenzelm@23252
   394
  let
wenzelm@23252
   395
   val tm = concl th
wenzelm@23252
   396
  in
wenzelm@23252
   397
   if not(is_add tm) then th else
wenzelm@23252
   398
   let val (lopr,r) = Thm.dest_comb tm
wenzelm@23252
   399
       val l = Thm.dest_arg lopr
wenzelm@23252
   400
   in
wenzelm@23252
   401
    if l aconvc zero_tm
wenzelm@23252
   402
    then transitive th (inst_thm [(ca,r)] pthm_07)   else
wenzelm@23252
   403
        if r aconvc zero_tm
wenzelm@23252
   404
        then transitive th (inst_thm [(ca,l)] pthm_08)  else th
wenzelm@23252
   405
   end
wenzelm@23252
   406
  end
wenzelm@23252
   407
 fun padd tm =
wenzelm@23252
   408
  let
wenzelm@23252
   409
   val (l,r) = dest_add tm
wenzelm@23252
   410
  in
wenzelm@23252
   411
   if l aconvc zero_tm then inst_thm [(ca,r)] pthm_07
wenzelm@23252
   412
   else if r aconvc zero_tm then inst_thm [(ca,l)] pthm_08
wenzelm@23252
   413
   else
wenzelm@23252
   414
    if is_add l
wenzelm@23252
   415
    then
wenzelm@23252
   416
     let val (a,b) = dest_add l
wenzelm@23252
   417
     in
wenzelm@23252
   418
     if is_add r then
wenzelm@23252
   419
      let val (c,d) = dest_add r
wenzelm@23252
   420
          val ord = morder a c
wenzelm@23252
   421
      in
wenzelm@23252
   422
       if ord = 0 then
wenzelm@23252
   423
        let val th1 = inst_thm [(ca,a),(cb,b),(cc,c),(cd,d)] pthm_23
wenzelm@23252
   424
            val (tm1,tm2) = Thm.dest_comb(concl th1)
wenzelm@23252
   425
            val (tm3,tm4) = Thm.dest_comb tm1
wenzelm@23252
   426
            val th2 = Drule.arg_cong_rule tm3 (monomial_add_conv tm4)
wenzelm@23252
   427
        in dezero_rule (transitive th1 (combination th2 (padd tm2)))
wenzelm@23252
   428
        end
wenzelm@23252
   429
       else (* ord <> 0*)
wenzelm@23252
   430
        let val th1 =
wenzelm@23252
   431
                if ord > 0 then inst_thm [(ca,a),(cb,b),(cc,r)] pthm_24
wenzelm@23252
   432
                else inst_thm [(ca,l),(cc,c),(cd,d)] pthm_25
wenzelm@23252
   433
            val (tm1,tm2) = Thm.dest_comb(concl th1)
wenzelm@23252
   434
        in dezero_rule (transitive th1 (Drule.arg_cong_rule tm1 (padd tm2)))
wenzelm@23252
   435
        end
wenzelm@23252
   436
      end
wenzelm@23252
   437
     else (* not (is_add r)*)
wenzelm@23252
   438
      let val ord = morder a r
wenzelm@23252
   439
      in
wenzelm@23252
   440
       if ord = 0 then
wenzelm@23252
   441
        let val th1 = inst_thm [(ca,a),(cb,b),(cc,r)] pthm_26
wenzelm@23252
   442
            val (tm1,tm2) = Thm.dest_comb(concl th1)
wenzelm@23252
   443
            val (tm3,tm4) = Thm.dest_comb tm1
wenzelm@23252
   444
            val th2 = Drule.fun_cong_rule (Drule.arg_cong_rule tm3 (monomial_add_conv tm4)) tm2
wenzelm@23252
   445
        in dezero_rule (transitive th1 th2)
wenzelm@23252
   446
        end
wenzelm@23252
   447
       else (* ord <> 0*)
wenzelm@23252
   448
        if ord > 0 then
wenzelm@23252
   449
          let val th1 = inst_thm [(ca,a),(cb,b),(cc,r)] pthm_24
wenzelm@23252
   450
              val (tm1,tm2) = Thm.dest_comb(concl th1)
wenzelm@23252
   451
          in dezero_rule (transitive th1 (Drule.arg_cong_rule tm1 (padd tm2)))
wenzelm@23252
   452
          end
wenzelm@23252
   453
        else dezero_rule (inst_thm [(ca,l),(cc,r)] pthm_27)
wenzelm@23252
   454
      end
wenzelm@23252
   455
    end
wenzelm@23252
   456
   else (* not (is_add l)*)
wenzelm@23252
   457
    if is_add r then
wenzelm@23252
   458
      let val (c,d) = dest_add r
wenzelm@23252
   459
          val  ord = morder l c
wenzelm@23252
   460
      in
wenzelm@23252
   461
       if ord = 0 then
wenzelm@23252
   462
         let val th1 = inst_thm [(ca,l),(cc,c),(cd,d)] pthm_28
wenzelm@23252
   463
             val (tm1,tm2) = Thm.dest_comb(concl th1)
wenzelm@23252
   464
             val (tm3,tm4) = Thm.dest_comb tm1
wenzelm@23252
   465
             val th2 = Drule.fun_cong_rule (Drule.arg_cong_rule tm3 (monomial_add_conv tm4)) tm2
wenzelm@23252
   466
         in dezero_rule (transitive th1 th2)
wenzelm@23252
   467
         end
wenzelm@23252
   468
       else
wenzelm@23252
   469
        if ord > 0 then reflexive tm
wenzelm@23252
   470
        else
wenzelm@23252
   471
         let val th1 = inst_thm [(ca,l),(cc,c),(cd,d)] pthm_25
wenzelm@23252
   472
             val (tm1,tm2) = Thm.dest_comb(concl th1)
wenzelm@23252
   473
         in dezero_rule (transitive th1 (Drule.arg_cong_rule tm1 (padd tm2)))
wenzelm@23252
   474
         end
wenzelm@23252
   475
      end
wenzelm@23252
   476
    else
wenzelm@23252
   477
     let val ord = morder l r
wenzelm@23252
   478
     in
wenzelm@23252
   479
      if ord = 0 then monomial_add_conv tm
wenzelm@23252
   480
      else if ord > 0 then dezero_rule(reflexive tm)
wenzelm@23252
   481
      else dezero_rule (inst_thm [(ca,l),(cc,r)] pthm_27)
wenzelm@23252
   482
     end
wenzelm@23252
   483
  end
wenzelm@23252
   484
 in padd
wenzelm@23252
   485
 end;
wenzelm@23252
   486
wenzelm@23252
   487
(* Multiplication of two polynomials.                                        *)
wenzelm@23252
   488
wenzelm@23252
   489
val polynomial_mul_conv =
wenzelm@23252
   490
 let
wenzelm@23252
   491
  fun pmul tm =
wenzelm@23252
   492
   let val (l,r) = dest_mul tm
wenzelm@23252
   493
   in
wenzelm@23252
   494
    if not(is_add l) then polynomial_monomial_mul_conv tm
wenzelm@23252
   495
    else
wenzelm@23252
   496
     if not(is_add r) then
wenzelm@23252
   497
      let val th1 = inst_thm [(ca,l),(cb,r)] pthm_09
wenzelm@23252
   498
      in transitive th1 (polynomial_monomial_mul_conv(concl th1))
wenzelm@23252
   499
      end
wenzelm@23252
   500
     else
wenzelm@23252
   501
       let val (a,b) = dest_add l
wenzelm@23252
   502
           val th1 = inst_thm [(ca,a),(cb,b),(cc,r)] pthm_10
wenzelm@23252
   503
           val (tm1,tm2) = Thm.dest_comb(concl th1)
wenzelm@23252
   504
           val (tm3,tm4) = Thm.dest_comb tm1
wenzelm@23252
   505
           val th2 = Drule.arg_cong_rule tm3 (polynomial_monomial_mul_conv tm4)
wenzelm@23252
   506
           val th3 = transitive th1 (combination th2 (pmul tm2))
wenzelm@23252
   507
       in transitive th3 (polynomial_add_conv (concl th3))
wenzelm@23252
   508
       end
wenzelm@23252
   509
   end
wenzelm@23252
   510
 in fn tm =>
wenzelm@23252
   511
   let val (l,r) = dest_mul tm
wenzelm@23252
   512
   in
wenzelm@23252
   513
    if l aconvc zero_tm then inst_thm [(ca,r)] pthm_11
wenzelm@23252
   514
    else if r aconvc zero_tm then inst_thm [(ca,l)] pthm_12
wenzelm@23252
   515
    else if l aconvc one_tm then inst_thm [(ca,r)] pthm_13
wenzelm@23252
   516
    else if r aconvc one_tm then inst_thm [(ca,l)] pthm_14
wenzelm@23252
   517
    else pmul tm
wenzelm@23252
   518
   end
wenzelm@23252
   519
 end;
wenzelm@23252
   520
wenzelm@23252
   521
(* Power of polynomial (optimized for the monomial and trivial cases).       *)
wenzelm@23252
   522
wenzelm@23580
   523
fun num_conv n =
wenzelm@23580
   524
  nat_add_conv (Thm.capply @{cterm Suc} (Numeral.mk_cnumber @{ctyp nat} (dest_numeral n - 1)))
wenzelm@23580
   525
  |> Thm.symmetric;
wenzelm@23252
   526
wenzelm@23252
   527
wenzelm@23252
   528
val polynomial_pow_conv =
wenzelm@23252
   529
 let
wenzelm@23252
   530
  fun ppow tm =
wenzelm@23252
   531
    let val (l,n) = dest_pow tm
wenzelm@23252
   532
    in
wenzelm@23252
   533
     if n aconvc zeron_tm then inst_thm [(cx,l)] pthm_35
wenzelm@23252
   534
     else if n aconvc onen_tm then inst_thm [(cx,l)] pthm_36
wenzelm@23252
   535
     else
wenzelm@23252
   536
         let val th1 = num_conv n
wenzelm@23252
   537
             val th2 = inst_thm [(cx,l),(cq,Thm.dest_arg (concl th1))] pthm_38
wenzelm@23252
   538
             val (tm1,tm2) = Thm.dest_comb(concl th2)
wenzelm@23252
   539
             val th3 = transitive th2 (Drule.arg_cong_rule tm1 (ppow tm2))
wenzelm@23252
   540
             val th4 = transitive (Drule.arg_cong_rule (Thm.dest_fun tm) th1) th3
wenzelm@23252
   541
         in transitive th4 (polynomial_mul_conv (concl th4))
wenzelm@23252
   542
         end
wenzelm@23252
   543
    end
wenzelm@23252
   544
 in fn tm =>
wenzelm@23252
   545
       if is_add(Thm.dest_arg1 tm) then ppow tm else monomial_pow_conv tm
wenzelm@23252
   546
 end;
wenzelm@23252
   547
wenzelm@23252
   548
(* Negation.                                                                 *)
wenzelm@23252
   549
wenzelm@23580
   550
fun polynomial_neg_conv tm =
wenzelm@23252
   551
   let val (l,r) = Thm.dest_comb tm in
wenzelm@23252
   552
        if not (l aconvc neg_tm) then raise CTERM ("polynomial_neg_conv",[tm]) else
wenzelm@23252
   553
        let val th1 = inst_thm [(cx',r)] neg_mul
wenzelm@23252
   554
            val th2 = transitive th1 (arg1_conv semiring_mul_conv (concl th1))
wenzelm@23252
   555
        in transitive th2 (polynomial_monomial_mul_conv (concl th2))
wenzelm@23252
   556
        end
wenzelm@23252
   557
   end;
wenzelm@23252
   558
wenzelm@23252
   559
wenzelm@23252
   560
(* Subtraction.                                                              *)
wenzelm@23580
   561
fun polynomial_sub_conv tm =
wenzelm@23252
   562
  let val (l,r) = dest_sub tm
wenzelm@23252
   563
      val th1 = inst_thm [(cx',l),(cy',r)] sub_add
wenzelm@23252
   564
      val (tm1,tm2) = Thm.dest_comb(concl th1)
wenzelm@23252
   565
      val th2 = Drule.arg_cong_rule tm1 (polynomial_neg_conv tm2)
wenzelm@23252
   566
  in transitive th1 (transitive th2 (polynomial_add_conv (concl th2)))
wenzelm@23252
   567
  end;
wenzelm@23252
   568
wenzelm@23252
   569
(* Conversion from HOL term.                                                 *)
wenzelm@23252
   570
wenzelm@23252
   571
fun polynomial_conv tm =
chaieb@23407
   572
 if is_semiring_constant tm then semiring_add_conv tm
chaieb@23407
   573
 else if not(is_comb tm) then reflexive tm
wenzelm@23252
   574
 else
wenzelm@23252
   575
  let val (lopr,r) = Thm.dest_comb tm
wenzelm@23252
   576
  in if lopr aconvc neg_tm then
wenzelm@23252
   577
       let val th1 = Drule.arg_cong_rule lopr (polynomial_conv r)
wenzelm@23252
   578
       in transitive th1 (polynomial_neg_conv (concl th1))
wenzelm@23252
   579
       end
wenzelm@23252
   580
     else
wenzelm@23252
   581
       if not(is_comb lopr) then reflexive tm
wenzelm@23252
   582
       else
wenzelm@23252
   583
         let val (opr,l) = Thm.dest_comb lopr
wenzelm@23252
   584
         in if opr aconvc pow_tm andalso is_numeral r
wenzelm@23252
   585
            then
wenzelm@23252
   586
              let val th1 = Drule.fun_cong_rule (Drule.arg_cong_rule opr (polynomial_conv l)) r
wenzelm@23252
   587
              in transitive th1 (polynomial_pow_conv (concl th1))
wenzelm@23252
   588
              end
wenzelm@23252
   589
            else
wenzelm@23252
   590
              if opr aconvc add_tm orelse opr aconvc mul_tm orelse opr aconvc sub_tm
wenzelm@23252
   591
              then
wenzelm@23252
   592
               let val th1 = combination (Drule.arg_cong_rule opr (polynomial_conv l)) (polynomial_conv r)
wenzelm@23252
   593
                   val f = if opr aconvc add_tm then polynomial_add_conv
wenzelm@23252
   594
                      else if opr aconvc mul_tm then polynomial_mul_conv
wenzelm@23252
   595
                      else polynomial_sub_conv
wenzelm@23252
   596
               in transitive th1 (f (concl th1))
wenzelm@23252
   597
               end
wenzelm@23252
   598
              else reflexive tm
wenzelm@23252
   599
         end
wenzelm@23252
   600
  end;
wenzelm@23252
   601
 in
wenzelm@23252
   602
   {main = polynomial_conv,
wenzelm@23252
   603
    add = polynomial_add_conv,
wenzelm@23252
   604
    mul = polynomial_mul_conv,
wenzelm@23252
   605
    pow = polynomial_pow_conv,
wenzelm@23252
   606
    neg = polynomial_neg_conv,
wenzelm@23252
   607
    sub = polynomial_sub_conv}
wenzelm@23252
   608
 end
wenzelm@23252
   609
end;
wenzelm@23252
   610
wenzelm@23252
   611
val nat_arith = @{thms "nat_arith"};
haftmann@25481
   612
val nat_exp_ss = HOL_basic_ss addsimps (@{thms nat_number} @ nat_arith @ @{thms arith_simps} @ @{thms rel_simps})
haftmann@23880
   613
                              addsimps [Let_def, if_False, if_True, @{thm add_0}, @{thm add_Suc}];
wenzelm@23252
   614
chaieb@23407
   615
fun simple_cterm_ord t u = Term.term_ord (term_of t, term_of u) = LESS;
chaieb@25253
   616
fun semiring_normalize_ord_wrapper ctxt ({vars, semiring, ring, idom, ideal}, 
chaieb@23407
   617
                                     {conv, dest_const, mk_const, is_const}) ord =
wenzelm@23252
   618
  let
wenzelm@23252
   619
    val pow_conv =
wenzelm@23252
   620
      arg_conv (Simplifier.rewrite nat_exp_ss)
wenzelm@23252
   621
      then_conv Simplifier.rewrite
wenzelm@23252
   622
        (HOL_basic_ss addsimps [nth (snd semiring) 31, nth (snd semiring) 34])
chaieb@23330
   623
      then_conv conv ctxt
chaieb@23330
   624
    val dat = (is_const, conv ctxt, conv ctxt, pow_conv)
wenzelm@23252
   625
    val {main, ...} = semiring_normalizers_conv vars semiring ring dat ord
wenzelm@23252
   626
  in main end;
wenzelm@23252
   627
chaieb@23407
   628
fun semiring_normalize_wrapper ctxt data = 
chaieb@23407
   629
  semiring_normalize_ord_wrapper ctxt data simple_cterm_ord;
chaieb@23407
   630
chaieb@23407
   631
fun semiring_normalize_ord_conv ctxt ord tm =
wenzelm@23252
   632
  (case NormalizerData.match ctxt tm of
wenzelm@23252
   633
    NONE => reflexive tm
chaieb@23407
   634
  | SOME res => semiring_normalize_ord_wrapper ctxt res ord tm);
chaieb@23407
   635
 
wenzelm@23252
   636
chaieb@23407
   637
fun semiring_normalize_conv ctxt = semiring_normalize_ord_conv ctxt simple_cterm_ord;
wenzelm@23252
   638
wenzelm@23252
   639
fun semiring_normalize_tac ctxt = SUBGOAL (fn (goal, i) =>
wenzelm@23252
   640
  rtac (semiring_normalize_conv ctxt
wenzelm@23252
   641
    (cterm_of (ProofContext.theory_of ctxt) (fst (Logic.dest_equals goal)))) i);
wenzelm@23252
   642
end;