(* Title: ZF/Tools/typechk.ML
Author: Lawrence C Paulson, Cambridge University Computer Laboratory
Copyright 1999 University of Cambridge
Automated type checking (cf. CTT).
*)
signature TYPE_CHECK =
sig
val print_tcset: Proof.context -> unit
val TC_add: attribute
val TC_del: attribute
val typecheck_tac: Proof.context -> tactic
val type_solver_tac: Proof.context -> thm list -> int -> tactic
val type_solver: solver
val setup: theory -> theory
end;
structure TypeCheck: TYPE_CHECK =
struct
(* datatype tcset *)
datatype tcset = TC of
{rules: thm list, (*the type-checking rules*)
net: thm Net.net}; (*discrimination net of the same rules*)
fun add_rule ctxt th (tcs as TC {rules, net}) =
if member Thm.eq_thm_prop rules th then
(warning ("Ignoring duplicate type-checking rule\n" ^ Display.string_of_thm ctxt th); tcs)
else
TC {rules = th :: rules, net = Net.insert_term (K false) (Thm.concl_of th, th) net};
fun del_rule ctxt th (tcs as TC {rules, net}) =
if member Thm.eq_thm_prop rules th then
TC {net = Net.delete_term Thm.eq_thm_prop (Thm.concl_of th, th) net,
rules = remove Thm.eq_thm_prop th rules}
else (warning ("No such type-checking rule\n" ^ Display.string_of_thm ctxt th); tcs);
(* generic data *)
structure Data = Generic_Data
(
type T = tcset;
val empty = TC {rules = [], net = Net.empty};
val extend = I;
fun merge (TC {rules, net}, TC {rules = rules', net = net'}) =
TC {rules = Thm.merge_thms (rules, rules'), net = Net.merge Thm.eq_thm_prop (net, net')};
);
val TC_add =
Thm.declaration_attribute (fn thm => fn context =>
Data.map (add_rule (Context.proof_of context) thm) context);
val TC_del =
Thm.declaration_attribute (fn thm => fn context =>
Data.map (del_rule (Context.proof_of context) thm) context);
val tcset_of = Data.get o Context.Proof;
fun print_tcset ctxt =
let val TC {rules, ...} = tcset_of ctxt in
Pretty.writeln (Pretty.big_list "type-checking rules:"
(map (Display.pretty_thm ctxt) rules))
end;
(* tactics *)
(*resolution using a net rather than rules*)
fun net_res_tac maxr net =
SUBGOAL
(fn (prem,i) =>
let val rls = Net.unify_term net (Logic.strip_assums_concl prem)
in
if length rls <= maxr then resolve_tac rls i else no_tac
end);
fun is_rigid_elem (Const(@{const_name Trueprop},_) $ (Const(@{const_name mem},_) $ a $ _)) =
not (is_Var (head_of a))
| is_rigid_elem _ = false;
(*Try solving a:A by assumption provided a is rigid!*)
val test_assume_tac = SUBGOAL(fn (prem,i) =>
if is_rigid_elem (Logic.strip_assums_concl prem)
then assume_tac i else eq_assume_tac i);
(*Type checking solves a:?A (a rigid, ?A maybe flexible).
match_tac is too strict; would refuse to instantiate ?A*)
fun typecheck_step_tac (TC{net,...}) =
FIRSTGOAL (test_assume_tac ORELSE' net_res_tac 3 net);
fun typecheck_tac ctxt = REPEAT (typecheck_step_tac (tcset_of ctxt));
(*Compiles a term-net for speed*)
val basic_res_tac = net_resolve_tac [@{thm TrueI}, @{thm refl}, reflexive_thm, @{thm iff_refl},
@{thm ballI}, @{thm allI}, @{thm conjI}, @{thm impI}];
(*Instantiates variables in typing conditions.
drawback: does not simplify conjunctions*)
fun type_solver_tac ctxt hyps = SELECT_GOAL
(DEPTH_SOLVE (etac @{thm FalseE} 1
ORELSE basic_res_tac 1
ORELSE (ares_tac hyps 1
APPEND typecheck_step_tac (tcset_of ctxt))));
val type_solver =
Simplifier.mk_solver "ZF typecheck" (fn ss =>
type_solver_tac (Simplifier.the_context ss) (Simplifier.prems_of ss));
(* concrete syntax *)
val typecheck_setup =
Method.setup @{binding typecheck}
(Method.sections
[Args.add -- Args.colon >> K (I, TC_add),
Args.del -- Args.colon >> K (I, TC_del)]
>> K (fn ctxt => SIMPLE_METHOD (CHANGED (typecheck_tac ctxt))))
"ZF type-checking";
val _ =
Outer_Syntax.improper_command "print_tcset" "print context of ZF typecheck" Keyword.diag
(Scan.succeed (Toplevel.no_timing o Toplevel.unknown_context o
Toplevel.keep (print_tcset o Toplevel.context_of)));
(* theory setup *)
val setup =
Attrib.setup @{binding TC} (Attrib.add_del TC_add TC_del) "declaration of type-checking rule" #>
typecheck_setup #>
Simplifier.map_simpset_global (fn ss => ss setSolver type_solver);
end;