(* Title: HOL/Arith.ML
ID: $Id$
Author: Lawrence C Paulson, Cambridge University Computer Laboratory
Copyright 1993 University of Cambridge
Proofs about elementary arithmetic: addition, multiplication, etc.
Some from the Hoare example from Norbert Galm
*)
open Arith;
(*** Basic rewrite rules for the arithmetic operators ***)
goalw Arith.thy [pred_def] "pred 0 = 0";
by(Simp_tac 1);
qed "pred_0";
goalw Arith.thy [pred_def] "pred(Suc n) = n";
by(Simp_tac 1);
qed "pred_Suc";
Addsimps [pred_0,pred_Suc];
(** pred **)
val prems = goal Arith.thy "n ~= 0 ==> Suc(pred n) = n";
by (res_inst_tac [("n","n")] natE 1);
by (cut_facts_tac prems 1);
by (ALLGOALS Asm_full_simp_tac);
qed "Suc_pred";
Addsimps [Suc_pred];
(** Difference **)
qed_goalw "diff_0_eq_0" Arith.thy [pred_def]
"0 - n = 0"
(fn _ => [induct_tac "n" 1, ALLGOALS Asm_simp_tac]);
(*Must simplify BEFORE the induction!! (Else we get a critical pair)
Suc(m) - Suc(n) rewrites to pred(Suc(m) - n) *)
qed_goalw "diff_Suc_Suc" Arith.thy [pred_def]
"Suc(m) - Suc(n) = m - n"
(fn _ =>
[Simp_tac 1, induct_tac "n" 1, ALLGOALS Asm_simp_tac]);
Addsimps [diff_0_eq_0, diff_Suc_Suc];
(**** Inductive properties of the operators ****)
(*** Addition ***)
qed_goal "add_0_right" Arith.thy "m + 0 = m"
(fn _ => [induct_tac "m" 1, ALLGOALS Asm_simp_tac]);
qed_goal "add_Suc_right" Arith.thy "m + Suc(n) = Suc(m+n)"
(fn _ => [induct_tac "m" 1, ALLGOALS Asm_simp_tac]);
Addsimps [add_0_right,add_Suc_right];
(*Associative law for addition*)
qed_goal "add_assoc" Arith.thy "(m + n) + k = m + ((n + k)::nat)"
(fn _ => [induct_tac "m" 1, ALLGOALS Asm_simp_tac]);
(*Commutative law for addition*)
qed_goal "add_commute" Arith.thy "m + n = n + (m::nat)"
(fn _ => [induct_tac "m" 1, ALLGOALS Asm_simp_tac]);
qed_goal "add_left_commute" Arith.thy "x+(y+z)=y+((x+z)::nat)"
(fn _ => [rtac (add_commute RS trans) 1, rtac (add_assoc RS trans) 1,
rtac (add_commute RS arg_cong) 1]);
(*Addition is an AC-operator*)
val add_ac = [add_assoc, add_commute, add_left_commute];
goal Arith.thy "!!k::nat. (k + m = k + n) = (m=n)";
by (induct_tac "k" 1);
by (Simp_tac 1);
by (Asm_simp_tac 1);
qed "add_left_cancel";
goal Arith.thy "!!k::nat. (m + k = n + k) = (m=n)";
by (induct_tac "k" 1);
by (Simp_tac 1);
by (Asm_simp_tac 1);
qed "add_right_cancel";
goal Arith.thy "!!k::nat. (k + m <= k + n) = (m<=n)";
by (induct_tac "k" 1);
by (Simp_tac 1);
by (Asm_simp_tac 1);
qed "add_left_cancel_le";
goal Arith.thy "!!k::nat. (k + m < k + n) = (m<n)";
by (induct_tac "k" 1);
by (Simp_tac 1);
by (Asm_simp_tac 1);
qed "add_left_cancel_less";
Addsimps [add_left_cancel, add_right_cancel,
add_left_cancel_le, add_left_cancel_less];
(** Reasoning about m+0=0, etc. **)
goal Arith.thy "(m+n = 0) = (m=0 & n=0)";
by (induct_tac "m" 1);
by (ALLGOALS Asm_simp_tac);
qed "add_is_0";
Addsimps [add_is_0];
goal Arith.thy "(pred (m+n) = 0) = (m=0 & pred n = 0 | pred m = 0 & n=0)";
by (induct_tac "m" 1);
by (ALLGOALS (fast_tac (!claset addss (!simpset))));
qed "pred_add_is_0";
Addsimps [pred_add_is_0];
goal Arith.thy "!!n. n ~= 0 ==> m + pred n = pred(m+n)";
by (induct_tac "m" 1);
by (ALLGOALS Asm_simp_tac);
qed "add_pred";
Addsimps [add_pred];
(**** Additional theorems about "less than" ****)
goal Arith.thy "i<j --> (EX k. j = Suc(i+k))";
by (induct_tac "j" 1);
by (Simp_tac 1);
by (blast_tac (!claset addSEs [less_SucE]
addSIs [add_0_right RS sym, add_Suc_right RS sym]) 1);
val lemma = result();
(* [| i<j; !!x. j = Suc(i+x) ==> Q |] ==> Q *)
bind_thm ("less_natE", lemma RS mp RS exE);
goal Arith.thy "!!m. m<n --> (? k. n=Suc(m+k))";
by (induct_tac "n" 1);
by (ALLGOALS (simp_tac (!simpset addsimps [less_Suc_eq])));
by (blast_tac (!claset addSEs [less_SucE]
addSIs [add_0_right RS sym, add_Suc_right RS sym]) 1);
qed_spec_mp "less_eq_Suc_add";
goal Arith.thy "n <= ((m + n)::nat)";
by (induct_tac "m" 1);
by (ALLGOALS Simp_tac);
by (etac le_trans 1);
by (rtac (lessI RS less_imp_le) 1);
qed "le_add2";
goal Arith.thy "n <= ((n + m)::nat)";
by (simp_tac (!simpset addsimps add_ac) 1);
by (rtac le_add2 1);
qed "le_add1";
bind_thm ("less_add_Suc1", (lessI RS (le_add1 RS le_less_trans)));
bind_thm ("less_add_Suc2", (lessI RS (le_add2 RS le_less_trans)));
(*"i <= j ==> i <= j+m"*)
bind_thm ("trans_le_add1", le_add1 RSN (2,le_trans));
(*"i <= j ==> i <= m+j"*)
bind_thm ("trans_le_add2", le_add2 RSN (2,le_trans));
(*"i < j ==> i < j+m"*)
bind_thm ("trans_less_add1", le_add1 RSN (2,less_le_trans));
(*"i < j ==> i < m+j"*)
bind_thm ("trans_less_add2", le_add2 RSN (2,less_le_trans));
goal Arith.thy "!!i. i+j < (k::nat) ==> i<k";
by (etac rev_mp 1);
by (induct_tac "j" 1);
by (ALLGOALS Asm_simp_tac);
by (blast_tac (!claset addDs [Suc_lessD]) 1);
qed "add_lessD1";
goal Arith.thy "!!i::nat. ~ (i+j < i)";
br notI 1;
be (add_lessD1 RS less_irrefl) 1;
qed "not_add_less1";
goal Arith.thy "!!i::nat. ~ (j+i < i)";
by (simp_tac (!simpset addsimps [add_commute, not_add_less1]) 1);
qed "not_add_less2";
AddIffs [not_add_less1, not_add_less2];
goal Arith.thy "!!k::nat. m <= n ==> m <= n+k";
by (etac le_trans 1);
by (rtac le_add1 1);
qed "le_imp_add_le";
goal Arith.thy "!!k::nat. m < n ==> m < n+k";
by (etac less_le_trans 1);
by (rtac le_add1 1);
qed "less_imp_add_less";
goal Arith.thy "m+k<=n --> m<=(n::nat)";
by (induct_tac "k" 1);
by (ALLGOALS Asm_simp_tac);
by (blast_tac (!claset addDs [Suc_leD]) 1);
qed_spec_mp "add_leD1";
goal Arith.thy "!!n::nat. m+k<=n ==> k<=n";
by (full_simp_tac (!simpset addsimps [add_commute]) 1);
by (etac add_leD1 1);
qed_spec_mp "add_leD2";
goal Arith.thy "!!n::nat. m+k<=n ==> m<=n & k<=n";
by (blast_tac (!claset addDs [add_leD1, add_leD2]) 1);
bind_thm ("add_leE", result() RS conjE);
goal Arith.thy "!!k l::nat. [| k<l; m+l = k+n |] ==> m<n";
by (safe_tac (!claset addSDs [less_eq_Suc_add]));
by (asm_full_simp_tac
(!simpset delsimps [add_Suc_right]
addsimps ([add_Suc_right RS sym, add_left_cancel] @add_ac)) 1);
by (etac subst 1);
by (simp_tac (!simpset addsimps [less_add_Suc1]) 1);
qed "less_add_eq_less";
(*** Monotonicity of Addition ***)
(*strict, in 1st argument*)
goal Arith.thy "!!i j k::nat. i < j ==> i + k < j + k";
by (induct_tac "k" 1);
by (ALLGOALS Asm_simp_tac);
qed "add_less_mono1";
(*strict, in both arguments*)
goal Arith.thy "!!i j k::nat. [|i < j; k < l|] ==> i + k < j + l";
by (rtac (add_less_mono1 RS less_trans) 1);
by (REPEAT (assume_tac 1));
by (induct_tac "j" 1);
by (ALLGOALS Asm_simp_tac);
qed "add_less_mono";
(*A [clumsy] way of lifting < monotonicity to <= monotonicity *)
val [lt_mono,le] = goal Arith.thy
"[| !!i j::nat. i<j ==> f(i) < f(j); \
\ i <= j \
\ |] ==> f(i) <= (f(j)::nat)";
by (cut_facts_tac [le] 1);
by (asm_full_simp_tac (!simpset addsimps [le_eq_less_or_eq]) 1);
by (blast_tac (!claset addSIs [lt_mono]) 1);
qed "less_mono_imp_le_mono";
(*non-strict, in 1st argument*)
goal Arith.thy "!!i j k::nat. i<=j ==> i + k <= j + k";
by (res_inst_tac [("f", "%j.j+k")] less_mono_imp_le_mono 1);
by (etac add_less_mono1 1);
by (assume_tac 1);
qed "add_le_mono1";
(*non-strict, in both arguments*)
goal Arith.thy "!!k l::nat. [|i<=j; k<=l |] ==> i + k <= j + l";
by (etac (add_le_mono1 RS le_trans) 1);
by (simp_tac (!simpset addsimps [add_commute]) 1);
(*j moves to the end because it is free while k, l are bound*)
by (etac add_le_mono1 1);
qed "add_le_mono";
(*** Multiplication ***)
(*right annihilation in product*)
qed_goal "mult_0_right" Arith.thy "m * 0 = 0"
(fn _ => [induct_tac "m" 1, ALLGOALS Asm_simp_tac]);
(*right successor law for multiplication*)
qed_goal "mult_Suc_right" Arith.thy "m * Suc(n) = m + (m * n)"
(fn _ => [induct_tac "m" 1,
ALLGOALS(asm_simp_tac (!simpset addsimps add_ac))]);
Addsimps [mult_0_right, mult_Suc_right];
goal Arith.thy "1 * n = n";
by (Asm_simp_tac 1);
qed "mult_1";
goal Arith.thy "n * 1 = n";
by (Asm_simp_tac 1);
qed "mult_1_right";
(*Commutative law for multiplication*)
qed_goal "mult_commute" Arith.thy "m * n = n * (m::nat)"
(fn _ => [induct_tac "m" 1, ALLGOALS Asm_simp_tac]);
(*addition distributes over multiplication*)
qed_goal "add_mult_distrib" Arith.thy "(m + n)*k = (m*k) + ((n*k)::nat)"
(fn _ => [induct_tac "m" 1,
ALLGOALS(asm_simp_tac (!simpset addsimps add_ac))]);
qed_goal "add_mult_distrib2" Arith.thy "k*(m + n) = (k*m) + ((k*n)::nat)"
(fn _ => [induct_tac "m" 1,
ALLGOALS(asm_simp_tac (!simpset addsimps add_ac))]);
(*Associative law for multiplication*)
qed_goal "mult_assoc" Arith.thy "(m * n) * k = m * ((n * k)::nat)"
(fn _ => [induct_tac "m" 1,
ALLGOALS (asm_simp_tac (!simpset addsimps [add_mult_distrib]))]);
qed_goal "mult_left_commute" Arith.thy "x*(y*z) = y*((x*z)::nat)"
(fn _ => [rtac trans 1, rtac mult_commute 1, rtac trans 1,
rtac mult_assoc 1, rtac (mult_commute RS arg_cong) 1]);
val mult_ac = [mult_assoc,mult_commute,mult_left_commute];
goal Arith.thy "(m*n = 0) = (m=0 | n=0)";
by (induct_tac "m" 1);
by (induct_tac "n" 2);
by (ALLGOALS Asm_simp_tac);
qed "mult_is_0";
Addsimps [mult_is_0];
(*** Difference ***)
qed_goal "pred_Suc_diff" Arith.thy "pred(Suc m - n) = m - n"
(fn _ => [induct_tac "n" 1, ALLGOALS Asm_simp_tac]);
Addsimps [pred_Suc_diff];
qed_goal "diff_self_eq_0" Arith.thy "m - m = 0"
(fn _ => [induct_tac "m" 1, ALLGOALS Asm_simp_tac]);
Addsimps [diff_self_eq_0];
(*Addition is the inverse of subtraction: if n<=m then n+(m-n) = m. *)
goal Arith.thy "~ m<n --> n+(m-n) = (m::nat)";
by (res_inst_tac [("m","m"),("n","n")] diff_induct 1);
by (ALLGOALS Asm_simp_tac);
qed_spec_mp "add_diff_inverse";
goal Arith.thy "!!m. n<=m ==> n+(m-n) = (m::nat)";
by (asm_simp_tac (!simpset addsimps [add_diff_inverse, not_less_iff_le]) 1);
qed "le_add_diff_inverse";
goal Arith.thy "!!m. n<=m ==> (m-n)+n = (m::nat)";
by (asm_simp_tac (!simpset addsimps [le_add_diff_inverse, add_commute]) 1);
qed "le_add_diff_inverse2";
Addsimps [le_add_diff_inverse, le_add_diff_inverse2];
Delsimps [diff_Suc];
(*** More results about difference ***)
val [prem] = goal Arith.thy "n < Suc(m) ==> Suc(m)-n = Suc(m-n)";
by (rtac (prem RS rev_mp) 1);
by (res_inst_tac [("m","m"),("n","n")] diff_induct 1);
by (ALLGOALS Asm_simp_tac);
qed "Suc_diff_n";
goal Arith.thy "m - n < Suc(m)";
by (res_inst_tac [("m","m"),("n","n")] diff_induct 1);
by (etac less_SucE 3);
by (ALLGOALS (asm_simp_tac (!simpset addsimps [less_Suc_eq])));
qed "diff_less_Suc";
goal Arith.thy "!!m::nat. m - n <= m";
by (res_inst_tac [("m","m"), ("n","n")] diff_induct 1);
by (ALLGOALS Asm_simp_tac);
qed "diff_le_self";
goal Arith.thy "!!i::nat. i-j-k = i - (j+k)";
by (res_inst_tac [("m","i"),("n","j")] diff_induct 1);
by (ALLGOALS Asm_simp_tac);
qed "diff_diff_left";
(*This and the next few suggested by Florian Kammueller*)
goal Arith.thy "!!i::nat. i-j-k = i-k-j";
by (simp_tac (!simpset addsimps [diff_diff_left, add_commute]) 1);
qed "diff_commute";
goal Arith.thy "!!i j k:: nat. k<=j --> j<=i --> i - (j - k) = i - j + k";
by (res_inst_tac [("m","i"),("n","j")] diff_induct 1);
by (ALLGOALS Asm_simp_tac);
by (asm_simp_tac
(!simpset addsimps [Suc_diff_n, le_imp_less_Suc, le_Suc_eq]) 1);
qed_spec_mp "diff_diff_right";
goal Arith.thy "!!i j k:: nat. k<=j --> (i + j) - k = i + (j - k)";
by (res_inst_tac [("m","j"),("n","k")] diff_induct 1);
by (ALLGOALS Asm_simp_tac);
qed_spec_mp "diff_add_assoc";
goal Arith.thy "!!n::nat. (n+m) - n = m";
by (induct_tac "n" 1);
by (ALLGOALS Asm_simp_tac);
qed "diff_add_inverse";
Addsimps [diff_add_inverse];
goal Arith.thy "!!n::nat.(m+n) - n = m";
by (simp_tac (!simpset addsimps [diff_add_assoc]) 1);
qed "diff_add_inverse2";
Addsimps [diff_add_inverse2];
goal Arith.thy "!!i j k::nat. i<=j ==> (j-i=k) = (j=k+i)";
by (Step_tac 1);
by (ALLGOALS Asm_simp_tac);
qed "le_imp_diff_is_add";
val [prem] = goal Arith.thy "m < Suc(n) ==> m-n = 0";
by (rtac (prem RS rev_mp) 1);
by (res_inst_tac [("m","m"),("n","n")] diff_induct 1);
by (asm_simp_tac (!simpset addsimps [less_Suc_eq]) 1);
by (ALLGOALS Asm_simp_tac);
qed "less_imp_diff_is_0";
val prems = goal Arith.thy "m-n = 0 --> n-m = 0 --> m=n";
by (res_inst_tac [("m","m"),("n","n")] diff_induct 1);
by (REPEAT(Simp_tac 1 THEN TRY(atac 1)));
qed_spec_mp "diffs0_imp_equal";
val [prem] = goal Arith.thy "m<n ==> 0<n-m";
by (rtac (prem RS rev_mp) 1);
by (res_inst_tac [("m","m"),("n","n")] diff_induct 1);
by (ALLGOALS Asm_simp_tac);
qed "less_imp_diff_positive";
goal Arith.thy "Suc(m)-n = (if m<n then 0 else Suc(m-n))";
by (simp_tac (!simpset addsimps [less_imp_diff_is_0, not_less_eq, Suc_diff_n]
setloop (split_tac [expand_if])) 1);
qed "if_Suc_diff_n";
goal Arith.thy "P(k) --> (!n. P(Suc(n))--> P(n)) --> P(k-i)";
by (res_inst_tac [("m","k"),("n","i")] diff_induct 1);
by (ALLGOALS (strip_tac THEN' Simp_tac THEN' TRY o Blast_tac));
qed "zero_induct_lemma";
val prems = goal Arith.thy "[| P(k); !!n. P(Suc(n)) ==> P(n) |] ==> P(0)";
by (rtac (diff_self_eq_0 RS subst) 1);
by (rtac (zero_induct_lemma RS mp RS mp) 1);
by (REPEAT (ares_tac ([impI,allI]@prems) 1));
qed "zero_induct";
goal Arith.thy "!!k::nat. (k+m) - (k+n) = m - n";
by (induct_tac "k" 1);
by (ALLGOALS Asm_simp_tac);
qed "diff_cancel";
Addsimps [diff_cancel];
goal Arith.thy "!!m::nat. (m+k) - (n+k) = m - n";
val add_commute_k = read_instantiate [("n","k")] add_commute;
by (asm_simp_tac (!simpset addsimps ([add_commute_k])) 1);
qed "diff_cancel2";
Addsimps [diff_cancel2];
(*From Clemens Ballarin*)
goal Arith.thy "!!n::nat. [| k<=n; n<=m |] ==> (m-k) - (n-k) = m-n";
by (subgoal_tac "k<=n --> n<=m --> (m-k) - (n-k) = m-n" 1);
by (Asm_full_simp_tac 1);
by (induct_tac "k" 1);
by (Simp_tac 1);
(* Induction step *)
by (subgoal_tac "Suc na <= m --> n <= m --> Suc na <= n --> \
\ Suc (m - Suc na) - Suc (n - Suc na) = m-n" 1);
by (Asm_full_simp_tac 1);
by (blast_tac (!claset addIs [le_trans]) 1);
by (auto_tac (!claset addIs [Suc_leD], !simpset delsimps [diff_Suc_Suc]));
by (asm_full_simp_tac (!simpset delsimps [Suc_less_eq]
addsimps [Suc_diff_n RS sym, le_eq_less_Suc]) 1);
qed "diff_right_cancel";
goal Arith.thy "!!n::nat. n - (n+m) = 0";
by (induct_tac "n" 1);
by (ALLGOALS Asm_simp_tac);
qed "diff_add_0";
Addsimps [diff_add_0];
(** Difference distributes over multiplication **)
goal Arith.thy "!!m::nat. (m - n) * k = (m * k) - (n * k)";
by (res_inst_tac [("m","m"),("n","n")] diff_induct 1);
by (ALLGOALS Asm_simp_tac);
qed "diff_mult_distrib" ;
goal Arith.thy "!!m::nat. k * (m - n) = (k * m) - (k * n)";
val mult_commute_k = read_instantiate [("m","k")] mult_commute;
by (simp_tac (!simpset addsimps [diff_mult_distrib, mult_commute_k]) 1);
qed "diff_mult_distrib2" ;
(*NOT added as rewrites, since sometimes they are used from right-to-left*)
(*** Monotonicity of Multiplication ***)
goal Arith.thy "!!i::nat. i<=j ==> i*k<=j*k";
by (induct_tac "k" 1);
by (ALLGOALS (asm_simp_tac (!simpset addsimps [add_le_mono])));
qed "mult_le_mono1";
(*<=monotonicity, BOTH arguments*)
goal Arith.thy "!!i::nat. [| i<=j; k<=l |] ==> i*k<=j*l";
by (etac (mult_le_mono1 RS le_trans) 1);
by (rtac le_trans 1);
by (stac mult_commute 2);
by (etac mult_le_mono1 2);
by (simp_tac (!simpset addsimps [mult_commute]) 1);
qed "mult_le_mono";
(*strict, in 1st argument; proof is by induction on k>0*)
goal Arith.thy "!!i::nat. [| i<j; 0<k |] ==> k*i < k*j";
by (eres_inst_tac [("i","0")] less_natE 1);
by (Asm_simp_tac 1);
by (induct_tac "x" 1);
by (ALLGOALS (asm_simp_tac (!simpset addsimps [add_less_mono])));
qed "mult_less_mono2";
goal Arith.thy "!!i::nat. [| i<j; 0<k |] ==> i*k < j*k";
bd mult_less_mono2 1;
by (ALLGOALS (asm_full_simp_tac (!simpset addsimps [mult_commute])));
qed "mult_less_mono1";
goal Arith.thy "(0 < m*n) = (0<m & 0<n)";
by (induct_tac "m" 1);
by (induct_tac "n" 2);
by (ALLGOALS Asm_simp_tac);
qed "zero_less_mult_iff";
goal Arith.thy "(m*n = 1) = (m=1 & n=1)";
by (induct_tac "m" 1);
by (Simp_tac 1);
by (induct_tac "n" 1);
by (Simp_tac 1);
by (fast_tac (!claset addss !simpset) 1);
qed "mult_eq_1_iff";
goal Arith.thy "!!k. 0<k ==> (m*k < n*k) = (m<n)";
by (safe_tac (!claset addSIs [mult_less_mono1]));
by (cut_facts_tac [less_linear] 1);
by (blast_tac (!claset addDs [mult_less_mono1] addEs [less_asym]) 1);
qed "mult_less_cancel2";
goal Arith.thy "!!k. 0<k ==> (k*m < k*n) = (m<n)";
bd mult_less_cancel2 1;
by (asm_full_simp_tac (!simpset addsimps [mult_commute]) 1);
qed "mult_less_cancel1";
Addsimps [mult_less_cancel1, mult_less_cancel2];
goal Arith.thy "!!k. 0<k ==> (m*k = n*k) = (m=n)";
by (cut_facts_tac [less_linear] 1);
by(Step_tac 1);
ba 2;
by (ALLGOALS (dtac mult_less_mono1 THEN' assume_tac));
by (ALLGOALS Asm_full_simp_tac);
qed "mult_cancel2";
goal Arith.thy "!!k. 0<k ==> (k*m = k*n) = (m=n)";
bd mult_cancel2 1;
by (asm_full_simp_tac (!simpset addsimps [mult_commute]) 1);
qed "mult_cancel1";
Addsimps [mult_cancel1, mult_cancel2];
(** Lemma for gcd **)
goal Arith.thy "!!m n. m = m*n ==> n=1 | m=0";
by (dtac sym 1);
by (rtac disjCI 1);
by (rtac nat_less_cases 1 THEN assume_tac 2);
by (fast_tac (!claset addSEs [less_SucE] addss !simpset) 1);
by (best_tac (!claset addDs [mult_less_mono2]
addss (!simpset addsimps [zero_less_eq RS sym])) 1);
qed "mult_eq_self_implies_10";
(*** Subtraction laws -- from Clemens Ballarin ***)
goal Arith.thy "!! a b c::nat. [| a < b; c <= a |] ==> a-c < b-c";
by (subgoal_tac "c+(a-c) < c+(b-c)" 1);
by (Full_simp_tac 1);
by (subgoal_tac "c <= b" 1);
by (blast_tac (!claset addIs [less_imp_le, le_trans]) 2);
by (Asm_simp_tac 1);
qed "diff_less_mono";
goal Arith.thy "!! a b c::nat. a+b < c ==> a < c-b";
bd diff_less_mono 1;
br le_add2 1;
by (Asm_full_simp_tac 1);
qed "add_less_imp_less_diff";
goal Arith.thy "!! n. n <= m ==> Suc m - n = Suc (m - n)";
br Suc_diff_n 1;
by (asm_full_simp_tac (!simpset addsimps [le_eq_less_Suc]) 1);
qed "Suc_diff_le";
goal Arith.thy "!! n. Suc i <= n ==> Suc (n - Suc i) = n - i";
by (asm_full_simp_tac
(!simpset addsimps [Suc_diff_n RS sym, le_eq_less_Suc]) 1);
qed "Suc_diff_Suc";
goal Arith.thy "!! i::nat. i <= n ==> n - (n - i) = i";
by (subgoal_tac "(n-i) + (n - (n-i)) = (n-i) + i" 1);
by (Full_simp_tac 1);
by (asm_simp_tac (!simpset addsimps [diff_le_self, add_commute]) 1);
qed "diff_diff_cancel";
Addsimps [diff_diff_cancel];
goal Arith.thy "!!k::nat. k <= n ==> m <= n + m - k";
be rev_mp 1;
by (res_inst_tac [("m", "k"), ("n", "n")] diff_induct 1);
by (Simp_tac 1);
by (simp_tac (!simpset addsimps [less_add_Suc2, less_imp_le]) 1);
by (Simp_tac 1);
qed "le_add_diff";