(* Title: HOL/Tools/Sledgehammer/sledgehammer_prover_minimize.ML Author: Philipp Meyer, TU Muenchen Author: Jasmin Blanchette, TU Muenchen Minimization of fact list for Metis using external provers. *) signature SLEDGEHAMMER_PROVER_MINIMIZE = sig type stature = ATP_Problem_Generate.stature type proof_method = Sledgehammer_Proof_Methods.proof_method type play_outcome = Sledgehammer_Proof_Methods.play_outcome type mode = Sledgehammer_Prover.mode type params = Sledgehammer_Prover.params type prover = Sledgehammer_Prover.prover val is_prover_supported : Proof.context -> string -> bool val is_prover_installed : Proof.context -> string -> bool val default_max_facts_of_prover : Proof.context -> string -> int val get_prover : Proof.context -> mode -> string -> prover val binary_min_facts : int Config.T val minimize_facts : (thm list -> unit) -> string -> params -> bool -> int -> int -> Proof.state -> thm -> ((string * stature) * thm list) list -> ((string * stature) * thm list) list option * ((unit -> (string * stature) list * (proof_method * play_outcome)) -> string) val get_minimizing_prover : Proof.context -> mode -> (thm list -> unit) -> string -> prover end; structure Sledgehammer_Prover_Minimize : SLEDGEHAMMER_PROVER_MINIMIZE = struct open ATP_Util open ATP_Proof open ATP_Problem_Generate open ATP_Proof_Reconstruct open ATP_Systems open Sledgehammer_Util open Sledgehammer_Fact open Sledgehammer_Proof_Methods open Sledgehammer_Isar open Sledgehammer_Prover open Sledgehammer_Prover_ATP open Sledgehammer_Prover_SMT fun is_prover_supported ctxt = let val thy = Proof_Context.theory_of ctxt in is_atp thy orf is_smt_prover ctxt end fun is_prover_installed ctxt = is_smt_prover ctxt orf is_atp_installed (Proof_Context.theory_of ctxt) fun default_max_facts_of_prover ctxt name = let val thy = Proof_Context.theory_of ctxt in if is_atp thy name then fold (Integer.max o fst o #1 o fst o snd) (#best_slices (get_atp thy name ()) ctxt) 0 else if is_smt_prover ctxt name then SMT_Solver.default_max_relevant ctxt name else error ("No such prover: " ^ name) end fun get_prover ctxt mode name = let val thy = Proof_Context.theory_of ctxt in if is_atp thy name then run_atp mode name else if is_smt_prover ctxt name then run_smt_solver mode name else error ("No such prover: " ^ name) end (* wrapper for calling external prover *) fun n_facts names = let val n = length names in string_of_int n ^ " fact" ^ plural_s n ^ (if n > 0 then ": " ^ (names |> map fst |> sort string_ord |> space_implode " ") else "") end fun print silent f = if silent then () else writeln (f ()) fun test_facts ({debug, verbose, overlord, spy, provers, max_mono_iters, max_new_mono_instances, type_enc, strict, lam_trans, uncurried_aliases, isar_proofs, compress, try0, smt_proofs, minimize, preplay_timeout, ...} : params) silent (prover : prover) timeout i n state goal facts = let val _ = print silent (fn () => "Testing " ^ n_facts (map fst facts) ^ (if verbose then " (timeout: " ^ string_of_time timeout ^ ")" else "") ^ "...") val facts = facts |> maps (fn (n, ths) => map (pair n) ths) val params = {debug = debug, verbose = verbose, overlord = overlord, spy = spy, provers = provers, type_enc = type_enc, strict = strict, lam_trans = lam_trans, uncurried_aliases = uncurried_aliases, learn = false, fact_filter = NONE, max_facts = SOME (length facts), fact_thresholds = (1.01, 1.01), max_mono_iters = max_mono_iters, max_new_mono_instances = max_new_mono_instances, isar_proofs = isar_proofs, compress = compress, try0 = try0, smt_proofs = smt_proofs, slice = false, minimize = minimize, timeout = timeout, preplay_timeout = preplay_timeout, expect = ""} val problem = {comment = "", state = state, goal = goal, subgoal = i, subgoal_count = n, factss = [("", facts)], found_proof = I} val result0 as {outcome = outcome0, used_facts, used_from, preferred_methss, run_time, message} = prover params problem val result as {outcome, ...} = if is_none outcome0 andalso forall (member (fn ((s, _), ((s', _), _)) => s = s') used_from) used_facts then result0 else {outcome = SOME MaybeUnprovable, used_facts = [], used_from = used_from, preferred_methss = preferred_methss, run_time = run_time, message = message} in print silent (fn () => (case outcome of SOME failure => string_of_atp_failure failure | NONE => "Found proof" ^ (if length used_facts = length facts then "" else " with " ^ n_facts used_facts) ^ " (" ^ string_of_time run_time ^ ")")); result end (* minimalization of facts *) (* Give the external prover some slack. The ATP gets further slack because the Sledgehammer preprocessing time is included in the estimate below but isn't part of the timeout. *) val slack_msecs = 200 fun new_timeout timeout run_time = Int.min (Time.toMilliseconds timeout, Time.toMilliseconds run_time + slack_msecs) |> Time.fromMilliseconds (* The linear algorithm usually outperforms the binary algorithm when over 60% of the facts are actually needed. The binary algorithm is much more appropriate for provers that cannot return the list of used facts and hence returns all facts as used. Since we cannot know in advance how many facts are actually needed, we heuristically set the threshold to 10 facts. *) val binary_min_facts = Attrib.setup_config_int \<^binding>\sledgehammer_minimize_binary_min_facts\ (K 20) fun linear_minimize test timeout result xs = let fun min _ [] p = p | min timeout (x :: xs) (seen, result) = (case test timeout (xs @ seen) of result as {outcome = NONE, used_facts, run_time, ...} : prover_result => min (new_timeout timeout run_time) (filter_used_facts true used_facts xs) (filter_used_facts false used_facts seen, result) | _ => min timeout xs (x :: seen, result)) in min timeout xs ([], result) end fun binary_minimize test timeout result xs = let fun min depth (result as {run_time, ...} : prover_result) sup (xs as _ :: _ :: _) = let val (l0, r0) = chop (length xs div 2) xs (* val _ = warning (replicate_string depth " " ^ "{ " ^ "sup: " ^ n_facts (map fst sup)) val _ = warning (replicate_string depth " " ^ " " ^ "xs: " ^ n_facts (map fst xs)) val _ = warning (replicate_string depth " " ^ " " ^ "l0: " ^ n_facts (map fst l0)) val _ = warning (replicate_string depth " " ^ " " ^ "r0: " ^ n_facts (map fst r0)) *) val depth = depth + 1 val timeout = new_timeout timeout run_time in (case test timeout (sup @ l0) of result as {outcome = NONE, used_facts, ...} => min depth result (filter_used_facts true used_facts sup) (filter_used_facts true used_facts l0) | _ => (case test timeout (sup @ r0) of result as {outcome = NONE, used_facts, ...} => min depth result (filter_used_facts true used_facts sup) (filter_used_facts true used_facts r0) | _ => let val (sup_r0, (l, result)) = min depth result (sup @ r0) l0 val (sup, r0) = (sup, r0) |> apply2 (filter_used_facts true (map fst sup_r0)) val (sup_l, (r, result)) = min depth result (sup @ l) r0 val sup = sup |> filter_used_facts true (map fst sup_l) in (sup, (l @ r, result)) end)) end (* |> tap (fn _ => warning (replicate_string depth " " ^ "}")) *) | min _ result sup xs = (sup, (xs, result)) in (case snd (min 0 result [] xs) of ([x], result as {run_time, ...}) => (case test (new_timeout timeout run_time) [] of result as {outcome = NONE, ...} => ([], result) | _ => ([x], result)) | p => p) end fun minimize_facts do_learn prover_name (params as {learn, timeout, ...}) silent i n state goal facts = let val ctxt = Proof.context_of state val prover = get_prover ctxt Minimize prover_name val (chained, non_chained) = List.partition is_fact_chained facts fun test timeout non_chained = test_facts params silent prover timeout i n state goal (chained @ non_chained) in (print silent (fn () => "Sledgehammer minimizer: " ^ quote prover_name); (case test timeout non_chained of result as {outcome = NONE, used_facts, run_time, ...} => let val non_chained = filter_used_facts true used_facts non_chained val min = if length non_chained >= Config.get ctxt binary_min_facts then binary_minimize else linear_minimize val (min_facts, {message, ...}) = min test (new_timeout timeout run_time) result non_chained val min_facts_and_chained = chained @ min_facts in print silent (fn () => cat_lines ["Minimized to " ^ n_facts (map fst min_facts)] ^ (case length chained of 0 => "" | n => " (plus " ^ string_of_int n ^ " chained)")); (if learn then do_learn (maps snd min_facts_and_chained) else ()); (SOME min_facts_and_chained, message) end | {outcome = SOME TimedOut, ...} => (NONE, fn _ => "Timeout: You can increase the time limit using the \"timeout\" option (e.g., \ \timeout = " ^ string_of_int (10 + Time.toMilliseconds timeout div 1000) ^ "\")") | {message, ...} => (NONE, (prefix "Prover error: " o message)))) handle ERROR msg => (NONE, fn _ => "Error: " ^ msg) end fun maybe_minimize mode do_learn name (params as {verbose, minimize, ...}) ({state, goal, subgoal, subgoal_count, ...} : prover_problem) (result as {outcome, used_facts, used_from, preferred_methss, run_time, message} : prover_result) = if is_some outcome then result else let val (used_facts, message) = if minimize then minimize_facts do_learn name params (not verbose orelse (mode <> Normal andalso mode <> MaSh)) subgoal subgoal_count state goal (filter_used_facts true used_facts (map (apsnd single) used_from)) |>> Option.map (map fst) else (SOME used_facts, message) in (case used_facts of SOME used_facts => {outcome = NONE, used_facts = sort_by fst used_facts, used_from = used_from, preferred_methss = preferred_methss, run_time = run_time, message = message} | NONE => result) end fun get_minimizing_prover ctxt mode do_learn name params problem = get_prover ctxt mode name params problem |> maybe_minimize mode do_learn name params problem end;