(* Author: Florian Haftmann, TU Muenchen *)
section \<open>A HOL random engine\<close>
theory Random
imports List Groups_List Code_Numeral
begin
subsection \<open>Auxiliary functions\<close>
fun log :: "natural \<Rightarrow> natural \<Rightarrow> natural" where
"log b i = (if b \<le> 1 \<or> i < b then 1 else 1 + log b (i div b))"
definition inc_shift :: "natural \<Rightarrow> natural \<Rightarrow> natural" where
"inc_shift v k = (if v = k then 1 else k + 1)"
definition minus_shift :: "natural \<Rightarrow> natural \<Rightarrow> natural \<Rightarrow> natural" where
"minus_shift r k l = (if k < l then r + k - l else k - l)"
subsection \<open>Random seeds\<close>
type_synonym seed = "natural \<times> natural"
primrec "next" :: "seed \<Rightarrow> natural \<times> seed" where
"next (v, w) = (let
k = v div 53668;
v' = minus_shift 2147483563 ((v mod 53668) * 40014) (k * 12211);
l = w div 52774;
w' = minus_shift 2147483399 ((w mod 52774) * 40692) (l * 3791);
z = minus_shift 2147483562 v' (w' + 1) + 1
in (z, (v', w')))"
definition split_seed :: "seed \<Rightarrow> seed \<times> seed" where
"split_seed s = (let
(v, w) = s;
(v', w') = snd (next s);
v'' = inc_shift 2147483562 v;
w'' = inc_shift 2147483398 w
in ((v'', w'), (v', w'')))"
subsection \<open>Base selectors\<close>
context
includes state_combinator_syntax
begin
fun iterate :: "natural \<Rightarrow> ('b \<Rightarrow> 'a \<Rightarrow> 'b \<times> 'a) \<Rightarrow> 'b \<Rightarrow> 'a \<Rightarrow> 'b \<times> 'a" where
"iterate k f x = (if k = 0 then Pair x else f x \<circ>\<rightarrow> iterate (k - 1) f)"
definition range :: "natural \<Rightarrow> seed \<Rightarrow> natural \<times> seed" where
"range k = iterate (log 2147483561 k)
(\<lambda>l. next \<circ>\<rightarrow> (\<lambda>v. Pair (v + l * 2147483561))) 1
\<circ>\<rightarrow> (\<lambda>v. Pair (v mod k))"
lemma range:
"k > 0 \<Longrightarrow> fst (range k s) < k"
by (simp add: range_def split_def less_natural_def del: log.simps iterate.simps)
definition select :: "'a list \<Rightarrow> seed \<Rightarrow> 'a \<times> seed" where
"select xs = range (natural_of_nat (length xs))
\<circ>\<rightarrow> (\<lambda>k. Pair (nth xs (nat_of_natural k)))"
lemma select:
assumes "xs \<noteq> []"
shows "fst (select xs s) \<in> set xs"
proof -
from assms have "natural_of_nat (length xs) > 0" by (simp add: less_natural_def)
with range have
"fst (range (natural_of_nat (length xs)) s) < natural_of_nat (length xs)" by best
then have
"nat_of_natural (fst (range (natural_of_nat (length xs)) s)) < length xs" by (simp add: less_natural_def)
then show ?thesis
by (simp add: split_beta select_def)
qed
primrec pick :: "(natural \<times> 'a) list \<Rightarrow> natural \<Rightarrow> 'a" where
"pick (x # xs) i = (if i < fst x then snd x else pick xs (i - fst x))"
lemma pick_member:
"i < sum_list (map fst xs) \<Longrightarrow> pick xs i \<in> set (map snd xs)"
by (induct xs arbitrary: i) (simp_all add: less_natural_def)
lemma pick_drop_zero:
"pick (filter (\<lambda>(k, _). k > 0) xs) = pick xs"
apply (induct xs)
apply (auto simp: fun_eq_iff less_natural.rep_eq split: prod.split)
by (metis diff_zero of_nat_0 of_nat_of_natural)
lemma pick_same:
"l < length xs \<Longrightarrow> Random.pick (map (Pair 1) xs) (natural_of_nat l) = nth xs l"
proof (induct xs arbitrary: l)
case Nil then show ?case by simp
next
case (Cons x xs) then show ?case by (cases l) (simp_all add: less_natural_def)
qed
definition select_weight :: "(natural \<times> 'a) list \<Rightarrow> seed \<Rightarrow> 'a \<times> seed" where
"select_weight xs = range (sum_list (map fst xs))
\<circ>\<rightarrow> (\<lambda>k. Pair (pick xs k))"
lemma select_weight_member:
assumes "0 < sum_list (map fst xs)"
shows "fst (select_weight xs s) \<in> set (map snd xs)"
proof -
from range assms
have "fst (range (sum_list (map fst xs)) s) < sum_list (map fst xs)" .
with pick_member
have "pick xs (fst (range (sum_list (map fst xs)) s)) \<in> set (map snd xs)" .
then show ?thesis by (simp add: select_weight_def scomp_def split_def)
qed
lemma select_weight_cons_zero:
"select_weight ((0, x) # xs) = select_weight xs"
by (simp add: select_weight_def less_natural_def)
lemma select_weight_drop_zero:
"select_weight (filter (\<lambda>(k, _). k > 0) xs) = select_weight xs"
proof -
have "sum_list (map fst [(k, _)\<leftarrow>xs . 0 < k]) = sum_list (map fst xs)"
by (induct xs) (auto simp add: less_natural_def natural_eq_iff)
then show ?thesis by (simp only: select_weight_def pick_drop_zero)
qed
lemma select_weight_select:
assumes "xs \<noteq> []"
shows "select_weight (map (Pair 1) xs) = select xs"
proof -
have less: "\<And>s. fst (range (natural_of_nat (length xs)) s) < natural_of_nat (length xs)"
using assms by (intro range) (simp add: less_natural_def)
moreover have "sum_list (map fst (map (Pair 1) xs)) = natural_of_nat (length xs)"
by (induct xs) simp_all
ultimately show ?thesis
by (auto simp add: select_weight_def select_def scomp_def split_def
fun_eq_iff pick_same [symmetric] less_natural_def)
qed
end
subsection \<open>\<open>ML\<close> interface\<close>
code_reflect Random_Engine
functions range select select_weight
ML \<open>
structure Random_Engine =
struct
open Random_Engine;
type seed = Code_Numeral.natural * Code_Numeral.natural;
local
val seed = Unsynchronized.ref
(let
val now = Time.toMilliseconds (Time.now ());
val (q, s1) = IntInf.divMod (now, 2147483562);
val s2 = q mod 2147483398;
in apply2 Code_Numeral.natural_of_integer (s1 + 1, s2 + 1) end);
in
fun next_seed () =
let
val (seed1, seed') = @{code split_seed} (! seed)
val _ = seed := seed'
in
seed1
end
fun run f =
let
val (x, seed') = f (! seed);
val _ = seed := seed'
in x end;
end;
end;
\<close>
hide_type (open) seed
hide_const (open) inc_shift minus_shift log "next" split_seed
iterate range select pick select_weight
hide_fact (open) range_def
end