Theory HOL.Quickcheck_Random
section ‹A simple counterexample generator performing random testing›
theory Quickcheck_Random
imports Random Code_Evaluation Enum
begin
setup ‹Code_Target.add_derived_target ("Quickcheck", [(Code_Runtime.target, I)])›
subsection ‹Catching Match exceptions›
axiomatization catch_match :: "'a => 'a => 'a"
code_printing
constant catch_match ⇀ (Quickcheck) "((_) handle Match => _)"
code_reserved Quickcheck Match
subsection ‹The ‹random› class›
class random = typerep +
fixes random :: "natural ⇒ Random.seed ⇒ ('a × (unit ⇒ term)) × Random.seed"
subsection ‹Fundamental and numeric types›
instantiation bool :: random
begin
context
includes state_combinator_syntax
begin
definition
"random i = Random.range 2 ∘→
(λk. Pair (if k = 0 then Code_Evaluation.valtermify False else Code_Evaluation.valtermify True))"
instance ..
end
end
instantiation itself :: (typerep) random
begin
definition
random_itself :: "natural ⇒ Random.seed ⇒ ('a itself × (unit ⇒ term)) × Random.seed"
where "random_itself _ = Pair (Code_Evaluation.valtermify TYPE('a))"
instance ..
end
instantiation char :: random
begin
context
includes state_combinator_syntax
begin
definition
"random _ = Random.select (Enum.enum :: char list) ∘→ (λc. Pair (c, λu. Code_Evaluation.term_of c))"
instance ..
end
end
instantiation String.literal :: random
begin
definition
"random _ = Pair (STR '''', λu. Code_Evaluation.term_of (STR ''''))"
instance ..
end
instantiation nat :: random
begin
context
includes state_combinator_syntax
begin
definition random_nat :: "natural ⇒ Random.seed
⇒ (nat × (unit ⇒ Code_Evaluation.term)) × Random.seed"
where
"random_nat i = Random.range (i + 1) ∘→ (λk. Pair (
let n = nat_of_natural k
in (n, λ_. Code_Evaluation.term_of n)))"
instance ..
end
end
instantiation int :: random
begin
context
includes state_combinator_syntax
begin
definition
"random i = Random.range (2 * i + 1) ∘→ (λk. Pair (
let j = (if k ≥ i then int (nat_of_natural (k - i)) else - (int (nat_of_natural (i - k))))
in (j, λ_. Code_Evaluation.term_of j)))"
instance ..
end
end
instantiation natural :: random
begin
context
includes state_combinator_syntax
begin
definition random_natural :: "natural ⇒ Random.seed
⇒ (natural × (unit ⇒ Code_Evaluation.term)) × Random.seed"
where
"random_natural i = Random.range (i + 1) ∘→ (λn. Pair (n, λ_. Code_Evaluation.term_of n))"
instance ..
end
end
instantiation integer :: random
begin
context
includes state_combinator_syntax
begin
definition random_integer :: "natural ⇒ Random.seed
⇒ (integer × (unit ⇒ Code_Evaluation.term)) × Random.seed"
where
"random_integer i = Random.range (2 * i + 1) ∘→ (λk. Pair (
let j = (if k ≥ i then integer_of_natural (k - i) else - (integer_of_natural (i - k)))
in (j, λ_. Code_Evaluation.term_of j)))"
instance ..
end
end
subsection ‹Complex generators›
text ‹Towards \<^typ>‹'a ⇒ 'b››
axiomatization random_fun_aux :: "typerep ⇒ typerep ⇒ ('a ⇒ 'a ⇒ bool) ⇒ ('a ⇒ term)
⇒ (Random.seed ⇒ ('b × (unit ⇒ term)) × Random.seed)
⇒ (Random.seed ⇒ Random.seed × Random.seed)
⇒ Random.seed ⇒ (('a ⇒ 'b) × (unit ⇒ term)) × Random.seed"
definition random_fun_lift :: "(Random.seed ⇒ ('b × (unit ⇒ term)) × Random.seed)
⇒ Random.seed ⇒ (('a::term_of ⇒ 'b::typerep) × (unit ⇒ term)) × Random.seed"
where
"random_fun_lift f =
random_fun_aux TYPEREP('a) TYPEREP('b) (=) Code_Evaluation.term_of f Random.split_seed"
instantiation "fun" :: ("{equal, term_of}", random) random
begin
definition
random_fun :: "natural ⇒ Random.seed ⇒ (('a ⇒ 'b) × (unit ⇒ term)) × Random.seed"
where "random i = random_fun_lift (random i)"
instance ..
end
text ‹Towards type copies and datatypes›
context
includes state_combinator_syntax
begin
definition collapse :: "('a ⇒ ('a ⇒ 'b × 'a) × 'a) ⇒ 'a ⇒ 'b × 'a"
where "collapse f = (f ∘→ id)"
end
definition beyond :: "natural ⇒ natural ⇒ natural"
where "beyond k l = (if l > k then l else 0)"
lemma beyond_zero: "beyond k 0 = 0"
by (simp add: beyond_def)
context
includes term_syntax
begin
definition [code_unfold]:
"valterm_emptyset = Code_Evaluation.valtermify ({} :: ('a :: typerep) set)"
definition [code_unfold]:
"valtermify_insert x s = Code_Evaluation.valtermify insert {⋅} (x :: ('a :: typerep * _)) {⋅} s"
end
instantiation set :: (random) random
begin
context
includes state_combinator_syntax
begin
fun random_aux_set
where
"random_aux_set 0 j = collapse (Random.select_weight [(1, Pair valterm_emptyset)])"
| "random_aux_set (Code_Numeral.Suc i) j =
collapse (Random.select_weight
[(1, Pair valterm_emptyset),
(Code_Numeral.Suc i,
random j ∘→ (%x. random_aux_set i j ∘→ (%s. Pair (valtermify_insert x s))))])"
lemma [code]:
"random_aux_set i j =
collapse (Random.select_weight [(1, Pair valterm_emptyset),
(i, random j ∘→ (%x. random_aux_set (i - 1) j ∘→ (%s. Pair (valtermify_insert x s))))])"
proof (induct i rule: natural.induct)
case zero
show ?case by (subst select_weight_drop_zero [symmetric])
(simp add: random_aux_set.simps [simplified] less_natural_def)
next
case (Suc i)
show ?case by (simp only: random_aux_set.simps(2) [of "i"] Suc_natural_minus_one)
qed
definition "random_set i = random_aux_set i i"
instance ..
end
end
lemma random_aux_rec:
fixes random_aux :: "natural ⇒ 'a"
assumes "random_aux 0 = rhs 0"
and "⋀k. random_aux (Code_Numeral.Suc k) = rhs (Code_Numeral.Suc k)"
shows "random_aux k = rhs k"
using assms by (rule natural.induct)
subsection ‹Deriving random generators for datatypes›
ML_file ‹Tools/Quickcheck/quickcheck_common.ML›
ML_file ‹Tools/Quickcheck/random_generators.ML›
subsection ‹Code setup›
code_printing
constant random_fun_aux ⇀ (Quickcheck) "Random'_Generators.random'_fun"
code_reserved Quickcheck Random_Generators
hide_const (open) catch_match random collapse beyond random_fun_aux random_fun_lift
hide_fact (open) collapse_def beyond_def random_fun_lift_def
end