tidying, removing obsolete lemmas about 0=... and 1=...
(* Title: HOL/nat_bin.ML
ID: $Id$
Author: Lawrence C Paulson, Cambridge University Computer Laboratory
Copyright 1999 University of Cambridge
Binary arithmetic for the natural numbers
*)
val nat_number_of_def = thm "nat_number_of_def";
(** nat (coercion from int to nat) **)
Goal "nat (number_of w) = number_of w";
by (simp_tac (simpset() addsimps [nat_number_of_def]) 1);
qed "nat_number_of";
Addsimps [nat_number_of];
(*These rewrites should one day be re-oriented...*)
Goal "#0 = (0::nat)";
by (simp_tac (HOL_basic_ss addsimps [nat_0, nat_number_of_def]) 1);
qed "numeral_0_eq_0";
Goal "#1 = (1::nat)";
by (simp_tac (HOL_basic_ss addsimps [nat_1, nat_number_of_def]) 1);
qed "numeral_1_eq_1";
Goal "#2 = (2::nat)";
by (simp_tac (HOL_basic_ss addsimps [nat_2, nat_number_of_def]) 1);
qed "numeral_2_eq_2";
bind_thm ("zero_eq_numeral_0", numeral_0_eq_0 RS sym);
(** int (coercion from nat to int) **)
(*"neg" is used in rewrite rules for binary comparisons*)
Goal "int (number_of v :: nat) = \
\ (if neg (number_of v) then #0 \
\ else (number_of v :: int))";
by (simp_tac
(simpset_of Int.thy addsimps [neg_nat, nat_number_of_def,
not_neg_nat, int_0]) 1);
qed "int_nat_number_of";
Addsimps [int_nat_number_of];
val nat_bin_arith_setup =
[Fast_Arith.map_data (fn {add_mono_thms, mult_mono_thms, inj_thms, lessD, simpset} =>
{add_mono_thms = add_mono_thms, mult_mono_thms = mult_mono_thms,
inj_thms = inj_thms,
lessD = lessD,
simpset = simpset addsimps [int_nat_number_of,
not_neg_number_of_Pls,neg_number_of_Min,neg_number_of_BIT]})];
(** Successor **)
Goal "(#0::int) <= z ==> Suc (nat z) = nat (#1 + z)";
by (rtac sym 1);
by (asm_simp_tac (simpset() addsimps [nat_eq_iff]) 1);
qed "Suc_nat_eq_nat_zadd1";
Goal "Suc (number_of v) = \
\ (if neg (number_of v) then #1 else number_of (bin_succ v))";
by (simp_tac
(simpset_of Int.thy addsimps [neg_nat, nat_1, not_neg_eq_ge_0,
nat_number_of_def, int_Suc,
Suc_nat_eq_nat_zadd1, number_of_succ]) 1);
qed "Suc_nat_number_of";
Addsimps [Suc_nat_number_of];
Goal "Suc (number_of v + n) = \
\ (if neg (number_of v) then #1+n else number_of (bin_succ v) + n)";
by (Simp_tac 1);
qed "Suc_nat_number_of_add";
Goal "Suc #0 = #1";
by (Simp_tac 1);
qed "Suc_numeral_0_eq_1";
Goal "Suc #1 = #2";
by (Simp_tac 1);
qed "Suc_numeral_1_eq_2";
(** Addition **)
Goal "[| (#0::int) <= z; #0 <= z' |] ==> nat (z+z') = nat z + nat z'";
by (rtac (inj_int RS injD) 1);
by (asm_simp_tac (simpset() addsimps [zadd_int RS sym]) 1);
qed "nat_add_distrib";
(*"neg" is used in rewrite rules for binary comparisons*)
Goal "(number_of v :: nat) + number_of v' = \
\ (if neg (number_of v) then number_of v' \
\ else if neg (number_of v') then number_of v \
\ else number_of (bin_add v v'))";
by (simp_tac
(simpset_of Int.thy addsimps [neg_nat, not_neg_eq_ge_0, nat_number_of_def,
nat_add_distrib RS sym, number_of_add]) 1);
qed "add_nat_number_of";
Addsimps [add_nat_number_of];
(** Subtraction **)
Goal "[| (#0::int) <= z'; z' <= z |] ==> nat (z-z') = nat z - nat z'";
by (rtac (inj_int RS injD) 1);
by (asm_simp_tac (simpset() addsimps [zdiff_int RS sym, nat_le_eq_zle]) 1);
qed "nat_diff_distrib";
Goal "nat z - nat z' = \
\ (if neg z' then nat z \
\ else let d = z-z' in \
\ if neg d then 0 else nat d)";
by (simp_tac (simpset() addsimps [Let_def, nat_diff_distrib RS sym,
neg_eq_less_0, not_neg_eq_ge_0]) 1);
by (simp_tac (simpset() addsimps [diff_is_0_eq, nat_le_eq_zle]) 1);
qed "diff_nat_eq_if";
Goalw [nat_number_of_def]
"(number_of v :: nat) - number_of v' = \
\ (if neg (number_of v') then number_of v \
\ else let d = number_of (bin_add v (bin_minus v')) in \
\ if neg d then #0 else nat d)";
by (simp_tac
(simpset_of Int.thy delcongs [if_weak_cong]
addsimps [not_neg_eq_ge_0, nat_0,
diff_nat_eq_if, diff_number_of_eq]) 1);
qed "diff_nat_number_of";
Addsimps [diff_nat_number_of];
(** Multiplication **)
Goal "(#0::int) <= z ==> nat (z*z') = nat z * nat z'";
by (case_tac "#0 <= z'" 1);
by (asm_full_simp_tac (simpset() addsimps [zmult_le_0_iff]) 2);
by (rtac (inj_int RS injD) 1);
by (asm_simp_tac (simpset() addsimps [zmult_int RS sym,
int_0_le_mult_iff]) 1);
qed "nat_mult_distrib";
Goal "z <= (#0::int) ==> nat(z*z') = nat(-z) * nat(-z')";
by (rtac trans 1);
by (rtac nat_mult_distrib 2);
by Auto_tac;
qed "nat_mult_distrib_neg";
Goal "(number_of v :: nat) * number_of v' = \
\ (if neg (number_of v) then #0 else number_of (bin_mult v v'))";
by (simp_tac
(simpset_of Int.thy addsimps [neg_nat, not_neg_eq_ge_0, nat_number_of_def,
nat_mult_distrib RS sym, number_of_mult,
nat_0]) 1);
qed "mult_nat_number_of";
Addsimps [mult_nat_number_of];
(** Quotient **)
Goal "(#0::int) <= z ==> nat (z div z') = nat z div nat z'";
by (case_tac "#0 <= z'" 1);
by (auto_tac (claset(),
simpset() addsimps [div_nonneg_neg_le0, DIVISION_BY_ZERO_DIV]));
by (zdiv_undefined_case_tac "z' = #0" 1);
by (simp_tac (simpset() addsimps [numeral_0_eq_0, DIVISION_BY_ZERO_DIV]) 1);
by (auto_tac (claset() addSEs [nonneg_eq_int], simpset()));
by (rename_tac "m m'" 1);
by (subgoal_tac "#0 <= int m div int m'" 1);
by (asm_full_simp_tac
(simpset() addsimps [numeral_0_eq_0, pos_imp_zdiv_nonneg_iff]) 2);
by (rtac (inj_int RS injD) 1);
by (Asm_simp_tac 1);
by (res_inst_tac [("r", "int (m mod m')")] quorem_div 1);
by (Force_tac 2);
by (asm_full_simp_tac
(simpset() addsimps [nat_less_iff RS sym, quorem_def,
numeral_0_eq_0, zadd_int, zmult_int]) 1);
by (rtac (mod_div_equality RS sym RS trans) 1);
by (asm_simp_tac (simpset() addsimps add_ac@mult_ac) 1);
qed "nat_div_distrib";
Goal "(number_of v :: nat) div number_of v' = \
\ (if neg (number_of v) then #0 \
\ else nat (number_of v div number_of v'))";
by (simp_tac
(simpset_of Int.thy addsimps [not_neg_eq_ge_0, nat_number_of_def, neg_nat,
nat_div_distrib RS sym, nat_0]) 1);
qed "div_nat_number_of";
Addsimps [div_nat_number_of];
(** Remainder **)
(*Fails if z'<0: the LHS collapses to (nat z) but the RHS doesn't*)
Goal "[| (#0::int) <= z; #0 <= z' |] ==> nat (z mod z') = nat z mod nat z'";
by (zdiv_undefined_case_tac "z' = #0" 1);
by (simp_tac (simpset() addsimps [numeral_0_eq_0, DIVISION_BY_ZERO_MOD]) 1);
by (auto_tac (claset() addSEs [nonneg_eq_int], simpset()));
by (rename_tac "m m'" 1);
by (subgoal_tac "#0 <= int m mod int m'" 1);
by (asm_full_simp_tac
(simpset() addsimps [nat_less_iff, numeral_0_eq_0, pos_mod_sign]) 2);
by (rtac (inj_int RS injD) 1);
by (Asm_simp_tac 1);
by (res_inst_tac [("q", "int (m div m')")] quorem_mod 1);
by (Force_tac 2);
by (asm_full_simp_tac
(simpset() addsimps [nat_less_iff RS sym, quorem_def,
numeral_0_eq_0, zadd_int, zmult_int]) 1);
by (rtac (mod_div_equality RS sym RS trans) 1);
by (asm_simp_tac (simpset() addsimps add_ac@mult_ac) 1);
qed "nat_mod_distrib";
Goal "(number_of v :: nat) mod number_of v' = \
\ (if neg (number_of v) then #0 \
\ else if neg (number_of v') then number_of v \
\ else nat (number_of v mod number_of v'))";
by (simp_tac
(simpset_of Int.thy addsimps [not_neg_eq_ge_0, nat_number_of_def,
neg_nat, nat_0, DIVISION_BY_ZERO_MOD,
nat_mod_distrib RS sym]) 1);
qed "mod_nat_number_of";
Addsimps [mod_nat_number_of];
(*** Comparisons ***)
(** Equals (=) **)
Goal "[| (#0::int) <= z; #0 <= z' |] ==> (nat z = nat z') = (z=z')";
by (auto_tac (claset() addSEs [nonneg_eq_int], simpset()));
qed "eq_nat_nat_iff";
(*"neg" is used in rewrite rules for binary comparisons*)
Goal "((number_of v :: nat) = number_of v') = \
\ (if neg (number_of v) then (iszero (number_of v') | neg (number_of v')) \
\ else if neg (number_of v') then iszero (number_of v) \
\ else iszero (number_of (bin_add v (bin_minus v'))))";
by (simp_tac
(simpset_of Int.thy addsimps [neg_nat, not_neg_eq_ge_0, nat_number_of_def,
eq_nat_nat_iff, eq_number_of_eq, nat_0]) 1);
by (simp_tac (simpset_of Int.thy addsimps [nat_eq_iff, nat_eq_iff2,
iszero_def]) 1);
by (simp_tac (simpset () addsimps [not_neg_eq_ge_0 RS sym]) 1);
qed "eq_nat_number_of";
Addsimps [eq_nat_number_of];
(** Less-than (<) **)
(*"neg" is used in rewrite rules for binary comparisons*)
Goal "((number_of v :: nat) < number_of v') = \
\ (if neg (number_of v) then neg (number_of (bin_minus v')) \
\ else neg (number_of (bin_add v (bin_minus v'))))";
by (simp_tac
(simpset_of Int.thy addsimps [neg_nat, not_neg_eq_ge_0, nat_number_of_def,
nat_less_eq_zless, less_number_of_eq_neg,
nat_0]) 1);
by (simp_tac (simpset_of Int.thy addsimps [neg_eq_less_int0, zminus_zless,
number_of_minus, zless_nat_eq_int_zless]) 1);
qed "less_nat_number_of";
Addsimps [less_nat_number_of];
(** Less-than-or-equals (<=) **)
Goal "(number_of x <= (number_of y::nat)) = \
\ (~ number_of y < (number_of x::nat))";
by (rtac (linorder_not_less RS sym) 1);
qed "le_nat_number_of_eq_not_less";
Addsimps [le_nat_number_of_eq_not_less];
(*** New versions of existing theorems involving 0, 1, 2 ***)
(*Maps n to #n for n = 0, 1, 2*)
val numeral_sym_ss =
HOL_ss addsimps [numeral_0_eq_0 RS sym,
numeral_1_eq_1 RS sym,
numeral_2_eq_2 RS sym,
Suc_numeral_1_eq_2, Suc_numeral_0_eq_1];
fun rename_numerals th = simplify numeral_sym_ss (Thm.transfer (the_context ()) th);
(*Maps #n to n for n = 0, 1, 2*)
val numeral_ss =
simpset() addsimps [numeral_0_eq_0, numeral_1_eq_1, numeral_2_eq_2];
(** Nat **)
Goal "#0 < n ==> n = Suc(n - #1)";
by (asm_full_simp_tac numeral_ss 1);
qed "Suc_pred'";
(*Expresses a natural number constant as the Suc of another one.
NOT suitable for rewriting because n recurs in the condition.*)
bind_thm ("expand_Suc", inst "n" "number_of ?v" Suc_pred');
(** NatDef & Nat **)
Addsimps (map rename_numerals [min_0L, min_0R, max_0L, max_0R]);
AddIffs (map rename_numerals
[Suc_not_Zero, Zero_not_Suc, zero_less_Suc, not_less0, less_one,
le0, le_0_eq, neq0_conv, not_gr0]);
(** Arith **)
(*Identity laws for + - * *)
val basic_renamed_arith_simps =
map rename_numerals
[diff_0, diff_0_eq_0, add_0, add_0_right,
mult_0, mult_0_right, mult_1, mult_1_right];
(*Non-trivial simplifications*)
val other_renamed_arith_simps =
map rename_numerals
[diff_is_0_eq, zero_less_diff,
mult_is_0, zero_less_mult_iff, mult_eq_1_iff];
Addsimps (basic_renamed_arith_simps @ other_renamed_arith_simps);
AddIffs (map rename_numerals [add_is_0, add_gr_0]);
Goal "Suc n = n + #1";
by (asm_simp_tac numeral_ss 1);
qed "Suc_eq_add_numeral_1";
(* These two can be useful when m = number_of... *)
Goal "(m::nat) + n = (if m=#0 then n else Suc ((m - #1) + n))";
by (case_tac "m" 1);
by (ALLGOALS (asm_simp_tac numeral_ss));
qed "add_eq_if";
Goal "(m::nat) * n = (if m=#0 then #0 else n + ((m - #1) * n))";
by (case_tac "m" 1);
by (ALLGOALS (asm_simp_tac numeral_ss));
qed "mult_eq_if";
Goal "(p ^ m :: nat) = (if m=#0 then #1 else p * (p ^ (m - #1)))";
by (case_tac "m" 1);
by (ALLGOALS (asm_simp_tac numeral_ss));
qed "power_eq_if";
Goal "[| #0<n; #0<m |] ==> m - n < (m::nat)";
by (asm_full_simp_tac (numeral_ss addsimps [diff_less]) 1);
qed "diff_less'";
Addsimps [inst "n" "number_of ?v" diff_less'];
(*various theorems that aren't in the default simpset*)
bind_thm ("add_is_one'", rename_numerals add_is_1);
bind_thm ("zero_induct'", rename_numerals zero_induct);
bind_thm ("diff_self_eq_0'", rename_numerals diff_self_eq_0);
bind_thm ("mult_eq_self_implies_10'", rename_numerals mult_eq_self_implies_10);
bind_thm ("le_pred_eq'", rename_numerals le_pred_eq);
bind_thm ("less_pred_eq'", rename_numerals less_pred_eq);
(** Divides **)
Addsimps (map rename_numerals [mod_1, mod_0, div_1, div_0]);
AddIffs (map rename_numerals [dvd_1_left, dvd_0_right]);
(*useful?*)
bind_thm ("mod_self'", rename_numerals mod_self);
bind_thm ("div_self'", rename_numerals div_self);
bind_thm ("div_less'", rename_numerals div_less);
bind_thm ("mod_mult_self_is_zero'", rename_numerals mod_mult_self_is_0);
(** Power **)
Goal "(p::nat) ^ #0 = #1";
by (simp_tac numeral_ss 1);
qed "power_zero";
Goal "(p::nat) ^ #1 = p";
by (simp_tac numeral_ss 1);
qed "power_one";
Addsimps [power_zero, power_one];
Goal "(p::nat) ^ #2 = p*p";
by (simp_tac numeral_ss 1);
qed "power_two";
Goal "#0 < (i::nat) ==> #0 < i^n";
by (asm_simp_tac numeral_ss 1);
qed "zero_less_power'";
Addsimps [zero_less_power'];
bind_thm ("binomial_zero", rename_numerals binomial_0);
bind_thm ("binomial_Suc'", rename_numerals binomial_Suc);
bind_thm ("binomial_n_n'", rename_numerals binomial_n_n);
(*binomial_0_Suc doesn't work well on numerals*)
Addsimps (map rename_numerals [binomial_n_0, binomial_zero, binomial_1]);
Addsimps [rename_numerals card_Pow];
(*** Comparisons involving (0::nat) ***)
Goal "(number_of v = (0::nat)) = \
\ (if neg (number_of v) then True else iszero (number_of v))";
by (simp_tac (simpset() addsimps [numeral_0_eq_0 RS sym]) 1);
qed "eq_number_of_0";
Goal "((0::nat) = number_of v) = \
\ (if neg (number_of v) then True else iszero (number_of v))";
by (rtac ([eq_sym_conv, eq_number_of_0] MRS trans) 1);
qed "eq_0_number_of";
Goal "((0::nat) < number_of v) = neg (number_of (bin_minus v))";
by (simp_tac (simpset() addsimps [numeral_0_eq_0 RS sym]) 1);
qed "less_0_number_of";
(*Simplification already handles n<0, n<=0 and 0<=n.*)
Addsimps [eq_number_of_0, eq_0_number_of, less_0_number_of];
Goal "neg (number_of v) ==> number_of v = (0::nat)";
by (asm_simp_tac (simpset() addsimps [numeral_0_eq_0 RS sym]) 1);
qed "neg_imp_number_of_eq_0";
(*** Comparisons involving Suc ***)
Goal "(number_of v = Suc n) = \
\ (let pv = number_of (bin_pred v) in \
\ if neg pv then False else nat pv = n)";
by (simp_tac
(simpset_of Int.thy addsimps
[Let_def, neg_eq_less_0, linorder_not_less, number_of_pred,
nat_number_of_def, zadd_0] @ zadd_ac) 1);
by (res_inst_tac [("x", "number_of v")] spec 1);
by (auto_tac (claset(), simpset() addsimps [nat_eq_iff]));
qed "eq_number_of_Suc";
Goal "(Suc n = number_of v) = \
\ (let pv = number_of (bin_pred v) in \
\ if neg pv then False else nat pv = n)";
by (rtac ([eq_sym_conv, eq_number_of_Suc] MRS trans) 1);
qed "Suc_eq_number_of";
Goal "(number_of v < Suc n) = \
\ (let pv = number_of (bin_pred v) in \
\ if neg pv then True else nat pv < n)";
by (simp_tac
(simpset_of Int.thy addsimps
[Let_def, neg_eq_less_0, linorder_not_less, number_of_pred,
nat_number_of_def, zadd_0] @ zadd_ac) 1);
by (res_inst_tac [("x", "number_of v")] spec 1);
by (auto_tac (claset(), simpset() addsimps [nat_less_iff]));
qed "less_number_of_Suc";
Goal "(Suc n < number_of v) = \
\ (let pv = number_of (bin_pred v) in \
\ if neg pv then False else n < nat pv)";
by (simp_tac
(simpset_of Int.thy addsimps
[Let_def, neg_eq_less_0, linorder_not_less, number_of_pred,
nat_number_of_def, zadd_0] @ zadd_ac) 1);
by (res_inst_tac [("x", "number_of v")] spec 1);
by (auto_tac (claset(), simpset() addsimps [zless_nat_eq_int_zless]));
qed "less_Suc_number_of";
Goal "(number_of v <= Suc n) = \
\ (let pv = number_of (bin_pred v) in \
\ if neg pv then True else nat pv <= n)";
by (simp_tac
(simpset () addsimps
[Let_def, less_Suc_number_of, linorder_not_less RS sym]) 1);
qed "le_number_of_Suc";
Goal "(Suc n <= number_of v) = \
\ (let pv = number_of (bin_pred v) in \
\ if neg pv then False else n <= nat pv)";
by (simp_tac
(simpset () addsimps
[Let_def, less_number_of_Suc, linorder_not_less RS sym]) 1);
qed "le_Suc_number_of";
Addsimps [eq_number_of_Suc, Suc_eq_number_of,
less_number_of_Suc, less_Suc_number_of,
le_number_of_Suc, le_Suc_number_of];
(* Push int(.) inwards: *)
Addsimps [int_Suc,zadd_int RS sym];
Goal "(m+m = n+n) = (m = (n::int))";
by Auto_tac;
val lemma1 = result();
Goal "m+m ~= int 1 + n + n";
by Auto_tac;
by (dres_inst_tac [("f", "%x. x mod #2")] arg_cong 1);
by (full_simp_tac (simpset() addsimps [zmod_zadd1_eq]) 1);
val lemma2 = result();
Goal "((number_of (v BIT x) ::int) = number_of (w BIT y)) = \
\ (x=y & (((number_of v) ::int) = number_of w))";
by (simp_tac (simpset_of Int.thy addsimps
[number_of_BIT, lemma1, lemma2, eq_commute]) 1);
qed "eq_number_of_BIT_BIT";
Goal "((number_of (v BIT x) ::int) = number_of Pls) = \
\ (x=False & (((number_of v) ::int) = number_of Pls))";
by (simp_tac (simpset_of Int.thy addsimps
[number_of_BIT, number_of_Pls, eq_commute]) 1);
by (res_inst_tac [("x", "number_of v")] spec 1);
by Safe_tac;
by (ALLGOALS Full_simp_tac);
by (dres_inst_tac [("f", "%x. x mod #2")] arg_cong 1);
by (full_simp_tac (simpset() addsimps [zmod_zadd1_eq]) 1);
qed "eq_number_of_BIT_Pls";
Goal "((number_of (v BIT x) ::int) = number_of Min) = \
\ (x=True & (((number_of v) ::int) = number_of Min))";
by (simp_tac (simpset_of Int.thy addsimps
[number_of_BIT, number_of_Min, eq_commute]) 1);
by (res_inst_tac [("x", "number_of v")] spec 1);
by Auto_tac;
by (dres_inst_tac [("f", "%x. x mod #2")] arg_cong 1);
by Auto_tac;
qed "eq_number_of_BIT_Min";
Goal "(number_of Pls ::int) ~= number_of Min";
by Auto_tac;
qed "eq_number_of_Pls_Min";
(*** Further lemmas about "nat" ***)
Goal "nat (abs (w * z)) = nat (abs w) * nat (abs z)";
by (case_tac "z=#0 | w=#0" 1);
by Auto_tac;
by (simp_tac (simpset() addsimps [zabs_def, nat_mult_distrib RS sym,
nat_mult_distrib_neg RS sym, zmult_less_0_iff]) 1);
by (arith_tac 1);
qed "nat_abs_mult_distrib";