(*  Title:      HOL/Library/Efficient_Nat.thy

    Author:     Stefan Berghofer, Florian Haftmann, TU Muenchen

*)

header {* Implementation of natural numbers by target-language integers *}

theory Efficient_Nat

imports Code_Index Code_Integer

begin

text {*

  When generating code for functions on natural numbers, the

  canonical representation using @{term "0::nat"} and

  @{term "Suc"} is unsuitable for computations involving large

  numbers.  The efficiency of the generated code can be improved

  drastically by implementing natural numbers by target-language

  integers.  To do this, just include this theory.

*}

subsection {* Basic arithmetic *}

text {*

  Most standard arithmetic functions on natural numbers are implemented

  using their counterparts on the integers:

*}

code_datatype number_nat_inst.number_of_nat

lemma zero_nat_code [code, code inline]:

  "0 = (Numeral0 :: nat)"

  by simp

lemmas [code post] = zero_nat_code [symmetric]

lemma one_nat_code [code, code inline]:

  "1 = (Numeral1 :: nat)"

  by simp

lemmas [code post] = one_nat_code [symmetric]

lemma Suc_code [code]:

  "Suc n = n + 1"

  by simp

lemma plus_nat_code [code]:

  "n + m = nat (of_nat n + of_nat m)"

  by simp

lemma minus_nat_code [code]:

  "n - m = nat (of_nat n - of_nat m)"

  by simp

lemma times_nat_code [code]:

  "n * m = nat (of_nat n * of_nat m)"

  unfolding of_nat_mult [symmetric] by simp

text {* Specialized @{term "op div \<Colon> nat \<Rightarrow> nat \<Rightarrow> nat"} 

  and @{term "op mod \<Colon> nat \<Rightarrow> nat \<Rightarrow> nat"} operations. *}

definition divmod_aux ::  "nat \<Rightarrow> nat \<Rightarrow> nat \<times> nat" where

  [code del]: "divmod_aux = divmod"

lemma [code]:

  "divmod n m = (if m = 0 then (0, n) else divmod_aux n m)"

  unfolding divmod_aux_def divmod_div_mod by simp

lemma divmod_aux_code [code]:

  "divmod_aux n m = (nat (of_nat n div of_nat m), nat (of_nat n mod of_nat m))"

  unfolding divmod_aux_def divmod_div_mod zdiv_int [symmetric] zmod_int [symmetric] by simp

lemma eq_nat_code [code]:

  "eq_class.eq n m \<longleftrightarrow> eq_class.eq (of_nat n \<Colon> int) (of_nat m)"

  by (simp add: eq)

lemma eq_nat_refl [code nbe]:

  "eq_class.eq (n::nat) n \<longleftrightarrow> True"

  by (rule HOL.eq_refl)

lemma less_eq_nat_code [code]:

  "n \<le> m \<longleftrightarrow> (of_nat n \<Colon> int) \<le> of_nat m"

  by simp

lemma less_nat_code [code]:

  "n < m \<longleftrightarrow> (of_nat n \<Colon> int) < of_nat m"

  by simp

subsection {* Case analysis *}

text {*

  Case analysis on natural numbers is rephrased using a conditional

  expression:

*}

lemma [code, code unfold]:

  "nat_case = (\<lambda>f g n. if n = 0 then f else g (n - 1))"

  by (auto simp add: expand_fun_eq dest!: gr0_implies_Suc)

subsection {* Preprocessors *}

text {*

  In contrast to @{term "Suc n"}, the term @{term "n + (1::nat)"} is no longer

  a constructor term. Therefore, all occurrences of this term in a position

  where a pattern is expected (i.e.\ on the left-hand side of a recursion

  equation or in the arguments of an inductive relation in an introduction

  rule) must be eliminated.

  This can be accomplished by applying the following transformation rules:

*}

lemma Suc_if_eq: "(\<And>n. f (Suc n) = h n) \<Longrightarrow> f 0 = g \<Longrightarrow>

  f n = (if n = 0 then g else h (n - 1))"

  by (case_tac n) simp_all

lemma Suc_clause: "(\<And>n. P n (Suc n)) \<Longrightarrow> n \<noteq> 0 \<Longrightarrow> P (n - 1) n"

  by (case_tac n) simp_all

text {*

  The rules above are built into a preprocessor that is plugged into

  the code generator. Since the preprocessor for introduction rules

  does not know anything about modes, some of the modes that worked

  for the canonical representation of natural numbers may no longer work.

*}

(*<*)

setup {*

let

fun remove_suc thy thms =

  let

    val vname = Name.variant (map fst

      (fold (Term.add_var_names o Thm.full_prop_of) thms [])) "x";

    val cv = cterm_of thy (Var ((vname, 0), HOLogic.natT));

    fun lhs_of th = snd (Thm.dest_comb

      (fst (Thm.dest_comb (snd (Thm.dest_comb (cprop_of th))))));

    fun rhs_of th = snd (Thm.dest_comb (snd (Thm.dest_comb (cprop_of th))));

    fun find_vars ct = (case term_of ct of

        (Const ("Suc", _) $ Var _) => [(cv, snd (Thm.dest_comb ct))]

      | _ $ _ =>

        let val (ct1, ct2) = Thm.dest_comb ct

        in 

          map (apfst (fn ct => Thm.capply ct ct2)) (find_vars ct1) @

          map (apfst (Thm.capply ct1)) (find_vars ct2)

        end

      | _ => []);

    val eqs = maps

      (fn th => map (pair th) (find_vars (lhs_of th))) thms;

    fun mk_thms (th, (ct, cv')) =

      let

        val th' =

          Thm.implies_elim

           (Conv.fconv_rule (Thm.beta_conversion true)

             (Drule.instantiate'

               [SOME (ctyp_of_term ct)] [SOME (Thm.cabs cv ct),

                 SOME (Thm.cabs cv' (rhs_of th)), NONE, SOME cv']

               @{thm Suc_if_eq})) (Thm.forall_intr cv' th)

      in

        case map_filter (fn th'' =>

            SOME (th'', singleton

              (Variable.trade (K (fn [th'''] => [th''' RS th'])) (Variable.thm_context th'')) th'')

          handle THM _ => NONE) thms of

            [] => NONE

          | thps =>

              let val (ths1, ths2) = split_list thps

              in SOME (subtract Thm.eq_thm (th :: ths1) thms @ ths2) end

      end

  in case get_first mk_thms eqs of

      NONE => thms

    | SOME x => remove_suc thy x

  end;

fun eqn_suc_preproc thy ths =

  let

    val dest = fst o HOLogic.dest_eq o HOLogic.dest_Trueprop o prop_of;

    fun contains_suc t = member (op =) (OldTerm.term_consts t) @{const_name Suc};

  in

    if forall (can dest) ths andalso

      exists (contains_suc o dest) ths

    then remove_suc thy ths else ths

  end;

fun remove_suc_clause thy thms =

  let

    val vname = Name.variant (map fst

      (fold (Term.add_var_names o Thm.full_prop_of) thms [])) "x";

    fun find_var (t as Const (@{const_name Suc}, _) $ (v as Var _)) = SOME (t, v)

      | find_var (t $ u) = (case find_var t of NONE => find_var u | x => x)

      | find_var _ = NONE;

    fun find_thm th =

      let val th' = Conv.fconv_rule ObjectLogic.atomize th

      in Option.map (pair (th, th')) (find_var (prop_of th')) end

  in

    case get_first find_thm thms of

      NONE => thms

    | SOME ((th, th'), (Sucv, v)) =>

        let

          val cert = cterm_of (Thm.theory_of_thm th);

          val th'' = ObjectLogic.rulify (Thm.implies_elim

            (Conv.fconv_rule (Thm.beta_conversion true)

              (Drule.instantiate' []

                [SOME (cert (lambda v (Abs ("x", HOLogic.natT,

                   abstract_over (Sucv,

                     HOLogic.dest_Trueprop (prop_of th')))))),

                 SOME (cert v)] @{thm Suc_clause}))

            (Thm.forall_intr (cert v) th'))

        in

          remove_suc_clause thy (map (fn th''' =>

            if (op = o pairself prop_of) (th''', th) then th'' else th''') thms)

        end

  end;

fun clause_suc_preproc thy ths =

  let

    val dest = fst o HOLogic.dest_mem o HOLogic.dest_Trueprop

  in

    if forall (can (dest o concl_of)) ths andalso

      exists (fn th => member (op =) (foldr OldTerm.add_term_consts

        [] (map_filter (try dest) (concl_of th :: prems_of th))) "Suc") ths

    then remove_suc_clause thy ths else ths

  end;

fun lift f thy eqns1 =

  let

    val eqns2 = burrow_fst Drule.zero_var_indexes_list eqns1;

    val thms3 = try (map fst

      #> map (fn thm => thm RS @{thm meta_eq_to_obj_eq})

      #> f thy

      #> map (fn thm => thm RS @{thm eq_reflection})

      #> map (Conv.fconv_rule Drule.beta_eta_conversion)) eqns2;

    val thms4 = Option.map Drule.zero_var_indexes_list thms3;

  in case thms4

   of NONE => NONE

    | SOME thms4 => if Thm.eq_thms (map fst eqns2, thms4)

        then NONE else SOME (map (apfst (AxClass.overload thy) o Code_Unit.mk_eqn thy) thms4)

  end

in

  Codegen.add_preprocessor eqn_suc_preproc

  #> Codegen.add_preprocessor clause_suc_preproc

  #> Code.add_functrans ("eqn_Suc", lift eqn_suc_preproc)

  #> Code.add_functrans ("clause_Suc", lift clause_suc_preproc)

end;

*}

(*>*)

subsection {* Target language setup *}

text {*

  For ML, we map @{typ nat} to target language integers, where we

  assert that values are always non-negative.

*}

code_type nat

  (SML "IntInf.int")

  (OCaml "Big'_int.big'_int")

types_code

  nat ("int")

attach (term_of) {*

val term_of_nat = HOLogic.mk_number HOLogic.natT;

*}

attach (test) {*

fun gen_nat i =

  let val n = random_range 0 i

  in (n, fn () => term_of_nat n) end;

*}

text {*

  For Haskell we define our own @{typ nat} type.  The reason

  is that we have to distinguish type class instances

  for @{typ nat} and @{typ int}.

*}

code_include Haskell "Nat" {*

newtype Nat = Nat Integer deriving (Show, Eq);

instance Num Nat where {

  fromInteger k = Nat (if k >= 0 then k else 0);

  Nat n + Nat m = Nat (n + m);

  Nat n - Nat m = fromInteger (n - m);

  Nat n * Nat m = Nat (n * m);

  abs n = n;

  signum _ = 1;

  negate n = error "negate Nat";

};

instance Ord Nat where {

  Nat n <= Nat m = n <= m;

  Nat n < Nat m = n < m;

};

instance Real Nat where {

  toRational (Nat n) = toRational n;

};

instance Enum Nat where {

  toEnum k = fromInteger (toEnum k);

  fromEnum (Nat n) = fromEnum n;

};

instance Integral Nat where {

  toInteger (Nat n) = n;

  divMod n m = quotRem n m;

  quotRem (Nat n) (Nat m) = (Nat k, Nat l) where (k, l) = quotRem n m;

};

*}

code_reserved Haskell Nat

code_type nat

  (Haskell "Nat")

code_instance nat :: eq

  (Haskell -)

text {*

  Natural numerals.

*}

lemma [code inline, symmetric, code post]:

  "nat (number_of i) = number_nat_inst.number_of_nat i"

  -- {* this interacts as desired with @{thm nat_number_of_def} *}

  by (simp add: number_nat_inst.number_of_nat)

setup {*

  fold (Numeral.add_code @{const_name number_nat_inst.number_of_nat}

    true false) ["SML", "OCaml", "Haskell"]

*}

text {*

  Since natural numbers are implemented

  using integers in ML, the coercion function @{const "of_nat"} of type

  @{typ "nat \<Rightarrow> int"} is simply implemented by the identity function.

  For the @{const "nat"} function for converting an integer to a natural

  number, we give a specific implementation using an ML function that

  returns its input value, provided that it is non-negative, and otherwise

  returns @{text "0"}.

*}

definition

  int :: "nat \<Rightarrow> int"

where

  [code del]: "int = of_nat"

lemma int_code' [code]:

  "int (number_of l) = (if neg (number_of l \<Colon> int) then 0 else number_of l)"

  unfolding int_nat_number_of [folded int_def] ..

lemma nat_code' [code]:

  "nat (number_of l) = (if neg (number_of l \<Colon> int) then 0 else number_of l)"

  unfolding nat_number_of_def number_of_is_id neg_def by simp

lemma of_nat_int [code unfold]:

  "of_nat = int" by (simp add: int_def)

declare of_nat_int [symmetric, code post]

code_const int

  (SML "_")

  (OCaml "_")

consts_code

  int ("(_)")

  nat ("\<module>nat")

attach {*

fun nat i = if i < 0 then 0 else i;

*}

code_const nat

  (SML "IntInf.max/ (/0,/ _)")

  (OCaml "Big'_int.max'_big'_int/ Big'_int.zero'_big'_int")

text {* For Haskell, things are slightly different again. *}

code_const int and nat

  (Haskell "toInteger" and "fromInteger")

text {* Conversion from and to indices. *}

code_const index_of_nat

  (SML "IntInf.toInt")

  (OCaml "Big'_int.int'_of'_big'_int")

  (Haskell "fromEnum")

code_const nat_of_index

  (SML "IntInf.fromInt")

  (OCaml "Big'_int.big'_int'_of'_int")

  (Haskell "toEnum")

text {* Using target language arithmetic operations whenever appropriate *}

code_const "op + \<Colon> nat \<Rightarrow> nat \<Rightarrow> nat"

  (SML "IntInf.+ ((_), (_))")

  (OCaml "Big'_int.add'_big'_int")

  (Haskell infixl 6 "+")

code_const "op * \<Colon> nat \<Rightarrow> nat \<Rightarrow> nat"

  (SML "IntInf.* ((_), (_))")

  (OCaml "Big'_int.mult'_big'_int")

  (Haskell infixl 7 "*")

code_const divmod_aux

  (SML "IntInf.divMod/ ((_),/ (_))")

  (OCaml "Big'_int.quomod'_big'_int")

  (Haskell "divMod")

code_const "eq_class.eq \<Colon> nat \<Rightarrow> nat \<Rightarrow> bool"

  (SML "!((_ : IntInf.int) = _)")

  (OCaml "Big'_int.eq'_big'_int")

  (Haskell infixl 4 "==")

code_const "op \<le> \<Colon> nat \<Rightarrow> nat \<Rightarrow> bool"

  (SML "IntInf.<= ((_), (_))")

  (OCaml "Big'_int.le'_big'_int")

  (Haskell infix 4 "<=")

code_const "op < \<Colon> nat \<Rightarrow> nat \<Rightarrow> bool"

  (SML "IntInf.< ((_), (_))")

  (OCaml "Big'_int.lt'_big'_int")

  (Haskell infix 4 "<")

consts_code

  "0::nat"                     ("0")

  "1::nat"                     ("1")

  Suc                          ("(_ +/ 1)")

  "op + \<Colon>  nat \<Rightarrow> nat \<Rightarrow> nat"   ("(_ +/ _)")

  "op * \<Colon>  nat \<Rightarrow> nat \<Rightarrow> nat"   ("(_ */ _)")

  "op \<le> \<Colon>  nat \<Rightarrow> nat \<Rightarrow> bool"  ("(_ <=/ _)")

  "op < \<Colon>  nat \<Rightarrow> nat \<Rightarrow> bool"  ("(_ </ _)")

text {* Evaluation *}

lemma [code, code del]:

  "(Code_Eval.term_of \<Colon> nat \<Rightarrow> term) = Code_Eval.term_of" ..

code_const "Code_Eval.term_of \<Colon> nat \<Rightarrow> term"

  (SML "HOLogic.mk'_number/ HOLogic.natT")

text {* Module names *}

code_modulename SML

  Nat Integer

  Divides Integer

  Ring_and_Field Integer

  Efficient_Nat Integer

code_modulename OCaml

  Nat Integer

  Divides Integer

  Ring_and_Field Integer

  Efficient_Nat Integer

code_modulename Haskell

  Nat Integer

  Divides Integer

  Ring_and_Field Integer

  Efficient_Nat Integer

hide const int

end