(* Title: HOL/ex/Primrec.thy
ID: $Id$
Author: Lawrence C Paulson, Cambridge University Computer Laboratory
Copyright 1997 University of Cambridge
Primitive Recursive Functions. Demonstrates recursive definitions,
the TFL package.
*)
header {* Primitive Recursive Functions *}
theory Primrec imports Main begin
text {*
Proof adopted from
Nora Szasz, A Machine Checked Proof that Ackermann's Function is not
Primitive Recursive, In: Huet \& Plotkin, eds., Logical Environments
(CUP, 1993), 317-338.
See also E. Mendelson, Introduction to Mathematical Logic. (Van
Nostrand, 1964), page 250, exercise 11.
\medskip
*}
consts ack :: "nat * nat => nat"
recdef ack "less_than <*lex*> less_than"
"ack (0, n) = Suc n"
"ack (Suc m, 0) = ack (m, 1)"
"ack (Suc m, Suc n) = ack (m, ack (Suc m, n))"
consts list_add :: "nat list => nat"
primrec
"list_add [] = 0"
"list_add (m # ms) = m + list_add ms"
consts zeroHd :: "nat list => nat"
primrec
"zeroHd [] = 0"
"zeroHd (m # ms) = m"
text {* The set of primitive recursive functions of type @{typ "nat list => nat"}. *}
definition
SC :: "nat list => nat" where
"SC l = Suc (zeroHd l)"
definition
CONSTANT :: "nat => nat list => nat" where
"CONSTANT k l = k"
definition
PROJ :: "nat => nat list => nat" where
"PROJ i l = zeroHd (drop i l)"
definition
COMP :: "(nat list => nat) => (nat list => nat) list => nat list => nat" where
"COMP g fs l = g (map (\<lambda>f. f l) fs)"
definition
PREC :: "(nat list => nat) => (nat list => nat) => nat list => nat" where
"PREC f g l =
(case l of
[] => 0
| x # l' => nat_rec (f l') (\<lambda>y r. g (r # y # l')) x)"
-- {* Note that @{term g} is applied first to @{term "PREC f g y"} and then to @{term y}! *}
inductive2 PRIMREC :: "(nat list => nat) => bool"
where
SC: "PRIMREC SC"
| CONSTANT: "PRIMREC (CONSTANT k)"
| PROJ: "PRIMREC (PROJ i)"
| COMP: "PRIMREC g ==> listsp PRIMREC fs ==> PRIMREC (COMP g fs)"
| PREC: "PRIMREC f ==> PRIMREC g ==> PRIMREC (PREC f g)"
text {* Useful special cases of evaluation *}
lemma SC [simp]: "SC (x # l) = Suc x"
apply (simp add: SC_def)
done
lemma CONSTANT [simp]: "CONSTANT k l = k"
apply (simp add: CONSTANT_def)
done
lemma PROJ_0 [simp]: "PROJ 0 (x # l) = x"
apply (simp add: PROJ_def)
done
lemma COMP_1 [simp]: "COMP g [f] l = g [f l]"
apply (simp add: COMP_def)
done
lemma PREC_0 [simp]: "PREC f g (0 # l) = f l"
apply (simp add: PREC_def)
done
lemma PREC_Suc [simp]: "PREC f g (Suc x # l) = g (PREC f g (x # l) # x # l)"
apply (simp add: PREC_def)
done
text {* PROPERTY A 4 *}
lemma less_ack2 [iff]: "j < ack (i, j)"
apply (induct i j rule: ack.induct)
apply simp_all
done
text {* PROPERTY A 5-, the single-step lemma *}
lemma ack_less_ack_Suc2 [iff]: "ack(i, j) < ack (i, Suc j)"
apply (induct i j rule: ack.induct)
apply simp_all
done
text {* PROPERTY A 5, monotonicity for @{text "<"} *}
lemma ack_less_mono2: "j < k ==> ack (i, j) < ack (i, k)"
apply (induct i k rule: ack.induct)
apply simp_all
apply (blast elim!: less_SucE intro: less_trans)
done
text {* PROPERTY A 5', monotonicity for @{text \<le>} *}
lemma ack_le_mono2: "j \<le> k ==> ack (i, j) \<le> ack (i, k)"
apply (simp add: order_le_less)
apply (blast intro: ack_less_mono2)
done
text {* PROPERTY A 6 *}
lemma ack2_le_ack1 [iff]: "ack (i, Suc j) \<le> ack (Suc i, j)"
apply (induct j)
apply simp_all
apply (blast intro: ack_le_mono2 less_ack2 [THEN Suc_leI] le_trans)
done
text {* PROPERTY A 7-, the single-step lemma *}
lemma ack_less_ack_Suc1 [iff]: "ack (i, j) < ack (Suc i, j)"
apply (blast intro: ack_less_mono2 less_le_trans)
done
text {* PROPERTY A 4'? Extra lemma needed for @{term CONSTANT} case, constant functions *}
lemma less_ack1 [iff]: "i < ack (i, j)"
apply (induct i)
apply simp_all
apply (blast intro: Suc_leI le_less_trans)
done
text {* PROPERTY A 8 *}
lemma ack_1 [simp]: "ack (Suc 0, j) = j + 2"
apply (induct j)
apply simp_all
done
text {* PROPERTY A 9. The unary @{text 1} and @{text 2} in @{term
ack} is essential for the rewriting. *}
lemma ack_2 [simp]: "ack (Suc (Suc 0), j) = 2 * j + 3"
apply (induct j)
apply simp_all
done
text {* PROPERTY A 7, monotonicity for @{text "<"} [not clear why
@{thm [source] ack_1} is now needed first!] *}
lemma ack_less_mono1_aux: "ack (i, k) < ack (Suc (i +i'), k)"
apply (induct i k rule: ack.induct)
apply simp_all
prefer 2
apply (blast intro: less_trans ack_less_mono2)
apply (induct_tac i' n rule: ack.induct)
apply simp_all
apply (blast intro: Suc_leI [THEN le_less_trans] ack_less_mono2)
done
lemma ack_less_mono1: "i < j ==> ack (i, k) < ack (j, k)"
apply (drule less_imp_Suc_add)
apply (blast intro!: ack_less_mono1_aux)
done
text {* PROPERTY A 7', monotonicity for @{text "\<le>"} *}
lemma ack_le_mono1: "i \<le> j ==> ack (i, k) \<le> ack (j, k)"
apply (simp add: order_le_less)
apply (blast intro: ack_less_mono1)
done
text {* PROPERTY A 10 *}
lemma ack_nest_bound: "ack(i1, ack (i2, j)) < ack (2 + (i1 + i2), j)"
apply (simp add: numerals)
apply (rule ack2_le_ack1 [THEN [2] less_le_trans])
apply simp
apply (rule le_add1 [THEN ack_le_mono1, THEN le_less_trans])
apply (rule ack_less_mono1 [THEN ack_less_mono2])
apply (simp add: le_imp_less_Suc le_add2)
done
text {* PROPERTY A 11 *}
lemma ack_add_bound: "ack (i1, j) + ack (i2, j) < ack (4 + (i1 + i2), j)"
apply (rule_tac j = "ack (Suc (Suc 0), ack (i1 + i2, j))" in less_trans)
prefer 2
apply (rule ack_nest_bound [THEN less_le_trans])
apply (simp add: Suc3_eq_add_3)
apply simp
apply (cut_tac i = i1 and m1 = i2 and k = j in le_add1 [THEN ack_le_mono1])
apply (cut_tac i = "i2" and m1 = i1 and k = j in le_add2 [THEN ack_le_mono1])
apply auto
done
text {* PROPERTY A 12. Article uses existential quantifier but the ALF proof
used @{text "k + 4"}. Quantified version must be nested @{text
"\<exists>k'. \<forall>i j. ..."} *}
lemma ack_add_bound2: "i < ack (k, j) ==> i + j < ack (4 + k, j)"
apply (rule_tac j = "ack (k, j) + ack (0, j)" in less_trans)
prefer 2
apply (rule ack_add_bound [THEN less_le_trans])
apply simp
apply (rule add_less_mono less_ack2 | assumption)+
done
text {* Inductive definition of the @{term PR} functions *}
text {* MAIN RESULT *}
lemma SC_case: "SC l < ack (1, list_add l)"
apply (unfold SC_def)
apply (induct l)
apply (simp_all add: le_add1 le_imp_less_Suc)
done
lemma CONSTANT_case: "CONSTANT k l < ack (k, list_add l)"
apply simp
done
lemma PROJ_case [rule_format]: "\<forall>i. PROJ i l < ack (0, list_add l)"
apply (simp add: PROJ_def)
apply (induct l)
apply simp_all
apply (rule allI)
apply (case_tac i)
apply (simp (no_asm_simp) add: le_add1 le_imp_less_Suc)
apply (simp (no_asm_simp))
apply (blast intro: less_le_trans intro!: le_add2)
done
text {* @{term COMP} case *}
lemma COMP_map_aux: "listsp (\<lambda>f. PRIMREC f \<and> (\<exists>kf. \<forall>l. f l < ack (kf, list_add l))) fs
==> \<exists>k. \<forall>l. list_add (map (\<lambda>f. f l) fs) < ack (k, list_add l)"
apply (erule listsp.induct)
apply (rule_tac x = 0 in exI)
apply simp
apply safe
apply simp
apply (rule exI)
apply (blast intro: add_less_mono ack_add_bound less_trans)
done
lemma COMP_case:
"\<forall>l. g l < ack (kg, list_add l) ==>
listsp (\<lambda>f. PRIMREC f \<and> (\<exists>kf. \<forall>l. f l < ack(kf, list_add l))) fs
==> \<exists>k. \<forall>l. COMP g fs l < ack(k, list_add l)"
apply (unfold COMP_def)
apply (subgoal_tac "listsp PRIMREC fs")
--{*Now, if meson tolerated map, we could finish with
@{text "(drule COMP_map_aux, meson ack_less_mono2 ack_nest_bound less_trans)"} *}
apply (erule COMP_map_aux [THEN exE])
apply (rule exI)
apply (rule allI)
apply (drule spec)+
apply (erule less_trans)
apply (blast intro: ack_less_mono2 ack_nest_bound less_trans)
apply simp
done
text {* @{term PREC} case *}
lemma PREC_case_aux:
"\<forall>l. f l + list_add l < ack (kf, list_add l) ==>
\<forall>l. g l + list_add l < ack (kg, list_add l) ==>
PREC f g l + list_add l < ack (Suc (kf + kg), list_add l)"
apply (unfold PREC_def)
apply (case_tac l)
apply simp_all
apply (blast intro: less_trans)
apply (erule ssubst) -- {* get rid of the needless assumption *}
apply (induct_tac a)
apply simp_all
txt {* base case *}
apply (blast intro: le_add1 [THEN le_imp_less_Suc, THEN ack_less_mono1] less_trans)
txt {* induction step *}
apply (rule Suc_leI [THEN le_less_trans])
apply (rule le_refl [THEN add_le_mono, THEN le_less_trans])
prefer 2
apply (erule spec)
apply (simp add: le_add2)
txt {* final part of the simplification *}
apply simp
apply (rule le_add2 [THEN ack_le_mono1, THEN le_less_trans])
apply (erule ack_less_mono2)
done
lemma PREC_case:
"\<forall>l. f l < ack (kf, list_add l) ==>
\<forall>l. g l < ack (kg, list_add l) ==>
\<exists>k. \<forall>l. PREC f g l < ack (k, list_add l)"
apply (rule exI)
apply (rule allI)
apply (rule le_less_trans [OF le_add1 PREC_case_aux])
apply (blast intro: ack_add_bound2)+
done
lemma ack_bounds_PRIMREC: "PRIMREC f ==> \<exists>k. \<forall>l. f l < ack (k, list_add l)"
apply (erule PRIMREC.induct)
apply (blast intro: SC_case CONSTANT_case PROJ_case COMP_case PREC_case)+
done
lemma ack_not_PRIMREC: "\<not> PRIMREC (\<lambda>l. case l of [] => 0 | x # l' => ack (x, x))"
apply (rule notI)
apply (erule ack_bounds_PRIMREC [THEN exE])
apply (rule less_irrefl)
apply (drule_tac x = "[x]" in spec)
apply simp
done
end