| Quellcodebibliothek Statistik Leitseite products/Sources/formale Sprachen/Isabelle/HOL/Tools/Predicate_Compile/ (Beweissystem Isabelle Version 2025-1©) Datei vom 16.11.2025 mit Größe 83 kB |
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Quelle predicate_compile_core.MLSprache: SML |
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(* Title: HOL/Tools/Predicate_Compile/predicate_compile_core.ML Author: Lukas Bulwahn, TU Muenchen A compiler from predicates specified by intro/elim rules to equations. *) signature PREDICATE_COMPILE_CORE = sig type seed = Random_Engine.seed type mode = Predicate_Compile_Aux.mode type options = Predicate_Compile_Aux.options type compilation = Predicate_Compile_Aux.compilation type compilation_funs = Predicate_Compile_Aux.compilation_funs val code_pred : options -> string -> Proof.context -> Proof.state val code_pred_cmd : options -> string -> Proof.context -> Proof.state val values_cmd : string list -> mode option list option -> ((string option * bool) * (compilation * int list)) -> int -> string -> Toplevel.state -> unit val values_timeout : real Config.T val print_stored_rules : Proof.context -> unit val print_all_modes : compilation -> Proof.context -> unit val put_pred_result : (unit -> term Predicate.pred) -> Proof.context -> Proof.context val put_pred_random_result : (unit -> seed -> term Predicate.pred * seed) -> Proof.context -> Proof.context val put_dseq_result : (unit -> term Limited_Sequence.dseq) -> Proof.context -> Proof.context val put_dseq_random_result : (unit -> Code_Numeral.natural -> Code_Numeral.natural -> seed -> term Limited_Sequence.dseq * seed) -> Proof.context -> Proof.context val put_new_dseq_result : (unit -> Code_Numeral.natural -> term Lazy_Sequence.lazy_sequenc Proof.context -> Proof.context val put_lseq_random_result : (unit -> Code_Numeral.natural -> Code_Numeral.natural -> seed -> Code_Numeral.natural -> term Lazy_Sequence.lazy_sequence) -> Proof.context -> Proof.context val put_lseq_random_stats_result : (unit -> Code_Numeral.natural -> Code_Numeral.natural -> seed -> Code_Numeral.natural -> (term * Code_Numeral.natural) Lazy_Sequence.lazy_sequence) -> Proof.context -> Proof.context val code_pred_intro_attrib : attribute (* used by Quickcheck_Generator *) (* temporary for testing of the compilation *) val add_equations : options -> string list -> theory -> theory val add_depth_limited_random_equations : options -> string list -> theory -> theory val add_random_dseq_equations : options -> string list -> theory -> theory val add_new_random_dseq_equations : options -> string list -> theory -> theory val add_generator_dseq_equations : options -> string list -> theory -> theory val add_generator_cps_equations : options -> string list -> theory -> theory val mk_tracing : string -> term -> term val prepare_intrs : options -> Proof.context -> string list -> thm list -> ((string * typ) list * string list * string list * (string * mode list) list * (string * (Term.term list * Predicate_Compile_Aux.indprem list) list) list) type mode_analysis_options = {use_generators : bool, reorder_premises : bool, infer_pos_and_neg_modes : bool} datatype mode_derivation = Mode_App of mode_derivation * mode_derivation | Context of mode | Mode_Pair of mode_derivation * mode_derivation | Term of mode val head_mode_of : mode_derivation -> mode type moded_clause = term list * (Predicate_Compile_Aux.indprem * mode_derivation) list type 'a pred_mode_table = (string * ((bool * mode) * 'a) list) list end; structure Predicate_Compile_Core : PREDICATE_COMPILE_CORE = struct type random_seed = Random_Engine.seed open Predicate_Compile_Aux; open Mode_Inference; open Predicate_Compile_Proof; type seed = Random_Engine.seed; (** fundamentals **) (* syntactic operations *) fun mk_eq (x, xs) = let fun mk_eqs _ [] = [] | mk_eqs a (b::cs) = HOLogic.mk_eq (Free (a, fastype_of b), b) :: mk_eqs a cs in mk_eqs x xs end; fun mk_tracing s t = Const(\<^const_name>\<open>Code_Evaluation.tracing\<close>, \<^typ>\<open>String.literal\<close> --> (fastype_of t) --> (fastype_of t)) $ (HOLogic.mk_litera (* representation of inferred clauses with modes *) type moded_clause = term list * (indprem * mode_derivation) list type 'a pred_mode_table = (string * ((bool * mode) * 'a) list) list (* diagnostic display functions *) fun print_modes options modes = if show_modes options then tracing ("Inferred modes:\n" ^ cat_lines (map (fn (s, ms) => s ^ ": " ^ commas (map (fn (p, m) => string_of_mode m ^ (if p then "pos" else "neg")) ms)) modes)) else () fun print_pred_mode_table string_of_entry pred_mode_table = let fun print_mode pred ((_, mode), entry) = "mode : " ^ string_of_mode mode ^ string_of_entry pred mode entry fun print_pred (pred, modes) = "predicate " ^ pred ^ ": " ^ cat_lines (map (print_mode pred) modes) val _ = tracing (cat_lines (map print_pred pred_mode_table)) in () end; fun print_compiled_terms options ctxt = if show_compilation options then print_pred_mode_table (fn _ => fn _ => Syntax.string_of_term ctxt) else K () fun print_stored_rules ctxt = let val preds = Graph.keys (Core_Data.PredData.get (Proof_Context.theory_of ctxt)) fun print pred () = let val _ = writeln ("predicate: " ^ pred) val _ = writeln ("introrules: ") val _ = fold (fn thm => fn _ => writeln (Thm.string_of_thm ctxt thm)) (rev (Core_Data.intros_of ctxt pred)) () in if Core_Data.has_elim ctxt pred then writeln ("elimrule: " ^ Thm.string_of_thm ctxt (Core_Data.the_elim_of ctxt pred)) else writeln ("no elimrule defined") end in fold print preds () end; fun print_all_modes compilation ctxt = let val _ = writeln ("Inferred modes:") fun print (pred, modes) u = let val _ = writeln ("predicate: " ^ pred) val _ = writeln ("modes: " ^ (commas (map string_of_mode modes))) in u end in fold print (Core_Data.all_modes_of compilation ctxt) () end (* validity checks *) fun check_expected_modes options _ modes = (case expected_modes options of SOME (s, ms) => (case AList.lookup (op =) modes s of SOME modes => let val modes' = map snd modes in if not (eq_set eq_mode (ms, modes')) then error ("expected modes were not inferred:\n" ^ " inferred modes for " ^ s ^ ": " ^ commas (map string_of_mode modes') ^ "\n" ^ " expected modes for " ^ s ^ ": " ^ commas (map string_of_mode ms)) else () end | NONE => ()) | NONE => ()) fun check_proposed_modes options preds modes errors = map (fn (s, _) => case proposed_modes options s of SOME ms => (case AList.lookup (op =) modes s of SOME inferred_ms => let val preds_without_modes = map fst (filter (null o snd) modes) val modes' = map snd inferred_ms in if not (eq_set eq_mode (ms, modes')) then error ("expected modes were not inferred:\n" ^ " inferred modes for " ^ s ^ ": " ^ commas (map string_of_mode modes') ^ "\n" ^ " expected modes for " ^ s ^ ": " ^ commas (map string_of_mode ms) ^ "\n" ^ (if show_invalid_clauses options then ("For the following clauses, the following modes could not be inferred: " ^ "\n" ^ cat_lines errors) else "") ^ (if not (null preds_without_modes) then "\n" ^ "No mode inferred for the predicates " ^ commas preds_without_modes else "")) else () end | NONE => ()) | NONE => ()) preds fun check_matches_type ctxt predname T ms = let fun check (Fun (m1, m2)) (Type("fun", [T1,T2])) = check m1 T1 andalso check m2 T2 | check m (Type("fun", _)) = (m = Input orelse m = Output) | check (Pair (m1, m2)) (Type (\<^type_name>\<open>Product_Type.prod\<close>, [T1, T2])) = check m1 T1 andalso check m2 T2 | check Input _ = true | check Output _ = true | check Bool \<^typ>\<open>bool\<close> = true | check _ _ = false fun check_consistent_modes ms = if forall (fn Fun _ => true | _ => false) ms then apply2 check_consistent_modes (split_list (map (fn Fun (m1, m2) => (m1, m2)) ms)) |> (fn (res1, res2) => res1 andalso res2) else if forall (fn Input => true | Output => true | Pair _ => true | _ => false) ms then true else if forall (fn Bool => true | _ => false) ms then true else false val _ = map (fn mode => if length (strip_fun_mode mode) = length (binder_types T) andalso (forall (uncurry check) (strip_fun_mode mode ~~ binder_types T)) then () else error (string_of_mode mode ^ " is not a valid mode for " ^ Syntax.string_of_typ ctxt T ^ " at predicate " ^ predname)) ms val _ = if check_consistent_modes ms then () else error (commas (map string_of_mode ms) ^ " are inconsistent modes for predicate " ^ predname) in ms end (* compilation modifiers *) structure Comp_Mod = (* FIXME proper signature *) struct datatype comp_modifiers = Comp_Modifiers of { compilation : compilation, function_name_prefix : string, compfuns : compilation_funs, mk_random : typ -> term list -> term, modify_funT : typ -> typ, additional_arguments : string list -> term list, wrap_compilation : compilation_funs -> string -> typ -> mode -> term list -> term -> term, transform_additional_arguments : indprem -> term list -> term list } fun dest_comp_modifiers (Comp_Modifiers c) = c val compilation = #compilation o dest_comp_modifiers val function_name_prefix = #function_name_prefix o dest_comp_modifiers val compfuns = #compfuns o dest_comp_modifiers val mk_random = #mk_random o dest_comp_modifiers val funT_of' = funT_of o compfuns val modify_funT = #modify_funT o dest_comp_modifiers fun funT_of comp mode = modify_funT comp o funT_of' comp mode val additional_arguments = #additional_arguments o dest_comp_modifiers val wrap_compilation = #wrap_compilation o dest_comp_modifiers val transform_additional_arguments = #transform_additional_arguments o dest_comp_modi fun set_compfuns compfuns' (Comp_Modifiers {compilation, function_name_prefix, compfun modify_funT, additional_arguments, wrap_compilation, transform_additional_arguments (Comp_Modifiers {compilation = compilation, function_name_prefix = function_name_prefi compfuns = compfuns', mk_random = mk_random, modify_funT = modify_funT, additional_arguments = additional_arguments, wrap_compilation = wrap_compilation, transform_additional_arguments = transform_additional_arguments}) end fun unlimited_compfuns_of true New_Pos_Random_DSeq = New_Pos_Random_Sequence_CompFuns.depth_unlimited_compfuns | unlimited_compfuns_of false New_Pos_Random_DSeq = New_Neg_Random_Sequence_CompFuns.depth_unlimited_compfuns | unlimited_compfuns_of true Pos_Generator_DSeq = New_Pos_DSequence_CompFuns.depth_unlimited_compfuns | unlimited_compfuns_of false Pos_Generator_DSeq = New_Neg_DSequence_CompFuns.depth_unlimited_compfuns | unlimited_compfuns_of _ c = raise Fail ("No unlimited compfuns for compilation " ^ string_of_compilation c) fun limited_compfuns_of true Predicate_Compile_Aux.New_Pos_Random_DSeq = New_Pos_Random_Sequence_CompFuns.depth_limited_compfuns | limited_compfuns_of false Predicate_Compile_Aux.New_Pos_Random_DSeq = New_Neg_Random_Sequence_CompFuns.depth_limited_compfuns | limited_compfuns_of true Pos_Generator_DSeq = New_Pos_DSequence_CompFuns.depth_limited_compfuns | limited_compfuns_of false Pos_Generator_DSeq = New_Neg_DSequence_CompFuns.depth_limited_compfuns | limited_compfuns_of _ c = raise Fail ("No limited compfuns for compilation " ^ string_of_compilation c) val depth_limited_comp_modifiers = Comp_Mod.Comp_Modifiers { compilation = Depth_Limited, function_name_prefix = "depth_limited_", compfuns = Predicate_Comp_Funs.compfuns, mk_random = (fn _ => error "no random generation"), additional_arguments = fn names => let val depth_name = singleton (Name.variant_list names) "depth" in [Free (depth_name, \<^typ>\<open>natural\<close>)] end, modify_funT = (fn T => let val (Ts, U) = strip_type T val Ts' = [\<^typ>\<open>natural\<close>] in (Ts @ Ts') ---> U end), wrap_compilation = fn compfuns => fn s => fn T => fn mode => fn additional_arguments => fn compilation => let val [depth] = additional_arguments val (_, Ts) = split_modeT mode (binder_types T) val T' = mk_monadT compfuns (HOLogic.mk_tupleT Ts) val if_const = Const (\<^const_name>\<open>If\<close>, \<^typ>\<open>bool\<close> --> T' --> T' --> T') in if_const $ HOLogic.mk_eq (depth, \<^term>\<open>0 :: natural\<close>) $ mk_empty compfuns (dest_monadT compfuns T') $ compilation end, transform_additional_arguments = fn _ => fn additional_arguments => let val [depth] = additional_arguments val depth' = Const (\<^const_name>\<open>Groups.minus\<close>, \<^typ>\<open>natural => natural => natural\<clos $ depth $ Const (\<^const_name>\<open>Groups.one\<close>, \<^typ>\<open>natural\<close>) in [depth'] end } val random_comp_modifiers = Comp_Mod.Comp_Modifiers { compilation = Random, function_name_prefix = "random_", compfuns = Predicate_Comp_Funs.compfuns, mk_random = (fn T => fn additional_arguments => list_comb (Const(\<^const_name>\<open>Random_Pred.iter\<close>, [\<^typ>\<open>natural\<close>, \<^typ>\<open>natural\<close>, \<^typ>\<open>Random.seed\<close>] ---> Predicate_Comp_Funs.mk_monadT T), additional_arguments)), modify_funT = (fn T => let val (Ts, U) = strip_type T val Ts' = [\<^typ>\<open>natural\<close>, \<^typ>\<open>natural\<close>, \<^typ>\<open>Random.seed\<cl in (Ts @ Ts') ---> U end), additional_arguments = (fn names => let val [nrandom, size, seed] = Name.variant_list names ["nrandom", "size", "seed"] in [Free (nrandom, \<^typ>\<open>natural\<close>), Free (size, \<^typ>\<open>natural\<close>), Free (seed, \<^typ>\<open>Random.seed\<close>)] end), wrap_compilation = K (K (K (K (K I)))) : (compilation_funs -> string -> typ -> mode -> term list -> term -> term), transform_additional_arguments = K I : (indprem -> term list -> term list) } val depth_limited_random_comp_modifiers = Comp_Mod.Comp_Modifiers { compilation = Depth_Limited_Random, function_name_prefix = "depth_limited_random_", compfuns = Predicate_Comp_Funs.compfuns, mk_random = (fn T => fn additional_arguments => list_comb (Const(\<^const_name>\<open>Random_Pred.iter\<close>, [\<^typ>\<open>natural\<close>, \<^typ>\<open>natural\<close>, \<^typ>\<open>Random.seed\<close>] ---> Predicate_Comp_Funs.mk_monadT T), tl additional_arguments)), modify_funT = (fn T => let val (Ts, U) = strip_type T val Ts' = [\<^typ>\<open>natural\<close>, \<^typ>\<open>natural\<close>, \<^typ>\<open>natural\<close>, \<^typ>\<open>Random.seed\<close>] in (Ts @ Ts') ---> U end), additional_arguments = (fn names => let val [depth, nrandom, size, seed] = Name.variant_list names ["depth", "nrandom", "size", "se in [Free (depth, \<^typ>\<open>natural\<close>), Free (nrandom, \<^typ>\<open>natural\<close>), Free (size, \<^typ>\<open>natural\<close>), Free (seed, \<^typ>\<open>Random.seed\<close>)] end), wrap_compilation = fn compfuns => fn _ => fn T => fn mode => fn additional_arguments => fn compilation => let val depth = hd (additional_arguments) val (_, Ts) = split_map_modeT (fn m => fn T => (SOME (funT_of compfuns m T), NONE)) mode (binder_types T) val T' = mk_monadT compfuns (HOLogic.mk_tupleT Ts) val if_const = Const (\<^const_name>\<open>If\<close>, \<^typ>\<open>bool\<close> --> T' --> T' --> T') in if_const $ HOLogic.mk_eq (depth, \<^term>\<open>0 :: natural\<close>) $ mk_empty compfuns (dest_monadT compfuns T') $ compilation end, transform_additional_arguments = fn _ => fn additional_arguments => let val [depth, nrandom, size, seed] = additional_arguments val depth' = Const (\<^const_name>\<open>Groups.minus\<close>, \<^typ>\<open>natural => natural => natural\<clos $ depth $ Const (\<^const_name>\<open>Groups.one\<close>, \<^typ>\<open>natural\<close>) in [depth', nrandom, size, seed] end } val predicate_comp_modifiers = Comp_Mod.Comp_Modifiers { compilation = Pred, function_name_prefix = "", compfuns = Predicate_Comp_Funs.compfuns, mk_random = (fn _ => error "no random generation"), modify_funT = I, additional_arguments = K [], wrap_compilation = K (K (K (K (K I)))) : (compilation_funs -> string -> typ -> mode -> term list -> term -> term), transform_additional_arguments = K I : (indprem -> term list -> term list) } val dseq_comp_modifiers = Comp_Mod.Comp_Modifiers { compilation = DSeq, function_name_prefix = "dseq_", compfuns = DSequence_CompFuns.compfuns, mk_random = (fn _ => error "no random generation in dseq"), modify_funT = I, additional_arguments = K [], wrap_compilation = K (K (K (K (K I)))) : (compilation_funs -> string -> typ -> mode -> term list -> term -> term), transform_additional_arguments = K I : (indprem -> term list -> term list) } val pos_random_dseq_comp_modifiers = Comp_Mod.Comp_Modifiers { compilation = Pos_Random_DSeq, function_name_prefix = "random_dseq_", compfuns = Random_Sequence_CompFuns.compfuns, mk_random = (fn T => fn _ => let val random = Const (\<^const_name>\<open>Quickcheck_Random.random\<close>, \<^typ>\<open>natural\<close> --> \<^typ>\<open>Random.seed\<close> --> HOLogic.mk_prodT (HOLogic.mk_prodT (T, \<^typ>\<open>unit => term\<close>), \<^typ>\<open>Random. in Const (\<^const_name>\<open>Random_Sequence.Random\<close>, (\<^typ>\<open>natural\<close> --> \<^ HOLogic.mk_prodT (HOLogic.mk_prodT (T, \<^typ>\<open>unit => term\<close>), \<^typ>\<open>Random. Random_Sequence_CompFuns.mk_random_dseqT T) $ random end), modify_funT = I, additional_arguments = K [], wrap_compilation = K (K (K (K (K I)))) : (compilation_funs -> string -> typ -> mode -> term list -> term -> term), transform_additional_arguments = K I : (indprem -> term list -> term list) } val neg_random_dseq_comp_modifiers = Comp_Mod.Comp_Modifiers { compilation = Neg_Random_DSeq, function_name_prefix = "random_dseq_neg_", compfuns = Random_Sequence_CompFuns.compfuns, mk_random = (fn _ => error "no random generation"), modify_funT = I, additional_arguments = K [], wrap_compilation = K (K (K (K (K I)))) : (compilation_funs -> string -> typ -> mode -> term list -> term -> term), transform_additional_arguments = K I : (indprem -> term list -> term list) } val new_pos_random_dseq_comp_modifiers = Comp_Mod.Comp_Modifiers { compilation = New_Pos_Random_DSeq, function_name_prefix = "new_random_dseq_", compfuns = New_Pos_Random_Sequence_CompFuns.depth_limited_compfuns, mk_random = (fn T => fn _ => let val random = Const (\<^const_name>\<open>Quickcheck_Random.random\<close>, \<^typ>\<open>natural\<close> --> \<^typ>\<open>Random.seed\<close> --> HOLogic.mk_prodT (HOLogic.mk_prodT (T, \<^typ>\<open>unit => term\<close>), \<^typ>\<open>Random. in Const (\<^const_name>\<open>Random_Sequence.pos_Random\<close>, (\<^typ>\<open>natural\<close> HOLogic.mk_prodT (HOLogic.mk_prodT (T, \<^typ>\<open>unit => term\<close>), \<^typ>\<open>Random. New_Pos_Random_Sequence_CompFuns.mk_pos_random_dseqT T) $ random end), modify_funT = I, additional_arguments = K [], wrap_compilation = K (K (K (K (K I)))) : (compilation_funs -> string -> typ -> mode -> term list -> term -> term), transform_additional_arguments = K I : (indprem -> term list -> term list) } val new_neg_random_dseq_comp_modifiers = Comp_Mod.Comp_Modifiers { compilation = New_Neg_Random_DSeq, function_name_prefix = "new_random_dseq_neg_", compfuns = New_Neg_Random_Sequence_CompFuns.depth_limited_compfuns, mk_random = (fn _ => error "no random generation"), modify_funT = I, additional_arguments = K [], wrap_compilation = K (K (K (K (K I)))) : (compilation_funs -> string -> typ -> mode -> term list -> term -> term), transform_additional_arguments = K I : (indprem -> term list -> term list) } val pos_generator_dseq_comp_modifiers = Comp_Mod.Comp_Modifiers { compilation = Pos_Generator_DSeq, function_name_prefix = "generator_dseq_", compfuns = New_Pos_DSequence_CompFuns.depth_limited_compfuns, mk_random = (fn T => fn _ => Const (\<^const_name>\<open>Lazy_Sequence.small_lazy_class.small_lazy\<close>, \<^typ>\<open>natural\<close> --> Type (\<^type_name>\<open>Lazy_Sequence.lazy_sequence\<close>, modify_funT = I, additional_arguments = K [], wrap_compilation = K (K (K (K (K I)))) : (compilation_funs -> string -> typ -> mode -> term list -> term -> term), transform_additional_arguments = K I : (indprem -> term list -> term list) } val neg_generator_dseq_comp_modifiers = Comp_Mod.Comp_Modifiers { compilation = Neg_Generator_DSeq, function_name_prefix = "generator_dseq_neg_", compfuns = New_Neg_DSequence_CompFuns.depth_limited_compfuns, mk_random = (fn _ => error "no random generation"), modify_funT = I, additional_arguments = K [], wrap_compilation = K (K (K (K (K I)))) : (compilation_funs -> string -> typ -> mode -> term list -> term -> term), transform_additional_arguments = K I : (indprem -> term list -> term list) } val pos_generator_cps_comp_modifiers = Comp_Mod.Comp_Modifiers { compilation = Pos_Generator_CPS, function_name_prefix = "generator_cps_pos_", compfuns = Pos_Bounded_CPS_Comp_Funs.compfuns, mk_random = (fn T => fn _ => Const (\<^const_name>\<open>Quickcheck_Exhaustive.exhaustive\<close>, (T --> \<^typ>\<open>(bool * term list) option\<close>) --> \<^typ>\<open>natural => (bool * term list) option\<close>)), modify_funT = I, additional_arguments = K [], wrap_compilation = K (K (K (K (K I)))) : (compilation_funs -> string -> typ -> mode -> term list -> term -> term), transform_additional_arguments = K I : (indprem -> term list -> term list) } val neg_generator_cps_comp_modifiers = Comp_Mod.Comp_Modifiers { compilation = Neg_Generator_CPS, function_name_prefix = "generator_cps_neg_", compfuns = Neg_Bounded_CPS_Comp_Funs.compfuns, mk_random = (fn _ => error "No enumerators"), modify_funT = I, additional_arguments = K [], wrap_compilation = K (K (K (K (K I)))) : (compilation_funs -> string -> typ -> mode -> term list -> term -> term), transform_additional_arguments = K I : (indprem -> term list -> term list) } fun negative_comp_modifiers_of comp_modifiers = (case Comp_Mod.compilation comp_modifiers of Pos_Random_DSeq => neg_random_dseq_comp_modifiers | Neg_Random_DSeq => pos_random_dseq_comp_modifiers | New_Pos_Random_DSeq => new_neg_random_dseq_comp_modifiers | New_Neg_Random_DSeq => new_pos_random_dseq_comp_modifiers | Pos_Generator_DSeq => neg_generator_dseq_comp_modifiers | Neg_Generator_DSeq => pos_generator_dseq_comp_modifiers | Pos_Generator_CPS => neg_generator_cps_comp_modifiers | Neg_Generator_CPS => pos_generator_cps_comp_modifiers | _ => comp_modifiers) (* term construction *) fun mk_v (names, vs) s T = (case AList.lookup (op =) vs s of NONE => (Free (s, T), (names, (s, [])::vs)) | SOME xs => let val s' = singleton (Name.variant_list names) s; val v = Free (s', T) in (v, (s'::names, AList.update (op =) (s, v::xs) vs)) end); fun distinct_v (Free (s, T)) nvs = mk_v nvs s T | distinct_v (t $ u) nvs = let val (t', nvs') = distinct_v t nvs; val (u', nvs'') = distinct_v u nvs'; in (t' $ u', nvs'') end | distinct_v x nvs = (x, nvs); (** specific rpred functions -- move them to the correct place in this file *) fun mk_Eval_of (P as (Free _), T) mode = let fun mk_bounds (Type (\<^type_name>\<open>Product_Type.prod\<close>, [T1, T2])) i = let val (bs2, i') = mk_bounds T2 i val (bs1, i'') = mk_bounds T1 i' in (HOLogic.pair_const T1 T2 $ bs1 $ bs2, i'' + 1) end | mk_bounds _ i = (Bound i, i + 1) fun mk_prod ((t1, T1), (t2, T2)) = (HOLogic.pair_const T1 T2 $ t1 $ t2, HOLogic.mk_prodT (T1, T2 fun mk_tuple [] = (HOLogic.unit, HOLogic.unitT) | mk_tuple tTs = foldr1 mk_prod tTs fun mk_split_abs (T as Type (\<^type_name>\<open>Product_Type.prod\<close>, [T1, T2])) t = absdummy T (HOLogic.case_prod_const (T1, T2, \<^typ>\<open>bool\<close>) $ (mk_split_abs T1 (mk_split_ab | mk_split_abs T t = absdummy T t val args = rev (fst (fold_map mk_bounds (rev (binder_types T)) 0)) val (inargs, outargs) = split_mode mode args val (_, outTs) = split_map_modeT (fn _ => fn T => (SOME T, NONE)) mode (binder_types T) val inner_term = Predicate_Comp_Funs.mk_Eval (list_comb (P, inargs), fst (mk_tuple (outar in fold_rev mk_split_abs (binder_types T) inner_term end fun compile_arg compilation_modifiers _ _ param_modes arg = let fun map_params (t as Free (f, T)) = (case (AList.lookup (op =) param_modes f) of SOME mode => let val T' = Comp_Mod.funT_of compilation_modifiers mode T in mk_Eval_of (Free (f, T'), T) mode end | NONE => t) | map_params t = t in map_aterms map_params arg end fun compile_match compilation_modifiers additional_arguments ctxt param_modes eqs eqs' out_ts success_t = let val compfuns = Comp_Mod.compfuns compilation_modifiers val eqs'' = maps mk_eq eqs @ eqs' val eqs'' = map (compile_arg compilation_modifiers additional_arguments ctxt param_modes) eqs'' val names = fold Term.add_free_names (success_t :: eqs'' @ out_ts) []; val name = singleton (Name.variant_list names) "x"; val name' = singleton (Name.variant_list (name :: names)) "y"; val T = HOLogic.mk_tupleT (map fastype_of out_ts); val U = fastype_of success_t; val U' = dest_monadT compfuns U; val v = Free (name, T); val v' = Free (name', T); in lambda v (Case_Translation.make_case ctxt Case_Translation.Quiet Name.context v [(HOLogic.mk_tuple out_ts, if null eqs'' then success_t else Const (\<^const_name>\<open>HOL.If\<close>, HOLogic.boolT --> U --> U --> U) $ foldr1 HOLogic.mk_conj eqs'' $ success_t $ mk_empty compfuns U'), (v', mk_empty compfuns U')]) end; fun compile_expr compilation_modifiers ctxt (t, deriv) param_modes additional_arguments let val compfuns = Comp_Mod.compfuns compilation_modifiers fun expr_of (t, deriv) = (case (t, deriv) of (t, Term Input) => SOME (compile_arg compilation_modifiers additional_arguments ctxt param_modes t) | (_, Term Output) => NONE | (Const (name, T), Context mode) => (case Core_Data.alternative_compilation_of ctxt name mode of SOME alt_comp => SOME (alt_comp compfuns T) | NONE => SOME (Const (Core_Data.function_name_of (Comp_Mod.compilation compilation_modifiers) ctxt name mode, Comp_Mod.funT_of compilation_modifiers mode T))) | (Free (s, T), Context m) => (case (AList.lookup (op =) param_modes s) of SOME _ => SOME (Free (s, Comp_Mod.funT_of compilation_modifiers m T)) | NONE => let val bs = map (pair "x") (binder_types (fastype_of t)) val bounds = map Bound (rev (0 upto (length bs) - 1)) in SOME (fold_rev Term.abs bs (mk_if compfuns (list_comb (t, bounds)))) end) | (t, Context _) => let val bs = map (pair "x") (binder_types (fastype_of t)) val bounds = map Bound (rev (0 upto (length bs) - 1)) in SOME (fold_rev Term.abs bs (mk_if compfuns (list_comb (t, bounds)))) end | (Const (\<^const_name>\<open>Pair\<close>, _) $ t1 $ t2, Mode_Pair (d1, d2)) => (case (expr_of (t1, d1), expr_of (t2, d2)) of (NONE, NONE) => NONE | (NONE, SOME t) => SOME t | (SOME t, NONE) => SOME t | (SOME t1, SOME t2) => SOME (HOLogic.mk_prod (t1, t2))) | (t1 $ t2, Mode_App (deriv1, deriv2)) => (case (expr_of (t1, deriv1), expr_of (t2, deriv2)) of (SOME t, NONE) => SOME t | (SOME t, SOME u) => SOME (t $ u) | _ => error "something went wrong here!")) in list_comb (the (expr_of (t, deriv)), additional_arguments) end fun compile_clause compilation_modifiers ctxt all_vs param_modes additional_arguments inp (in_ts, out_ts) moded_ps = let val compfuns = Comp_Mod.compfuns compilation_modifiers val compile_match = compile_match compilation_modifiers additional_arguments ctxt param_modes val (in_ts', (all_vs', eqs)) = fold_map (collect_non_invertible_subterms ctxt) in_ts (all_vs, []); fun compile_prems out_ts' vs names [] = let val (out_ts'', (names', eqs')) = fold_map (collect_non_invertible_subterms ctxt) out_ts' (names, []); val (out_ts''', (_, constr_vs)) = fold_map distinct_v out_ts'' (names', map (rpair []) vs); val processed_out_ts = map (compile_arg compilation_modifiers additional_arguments ctxt param_modes) out_ts in compile_match constr_vs (eqs @ eqs') out_ts''' (mk_single compfuns (HOLogic.mk_tuple processed_out_ts)) end | compile_prems out_ts vs names ((p, deriv) :: ps) = let val vs' = distinct (op =) (flat (vs :: map term_vs out_ts)); val (out_ts', (names', eqs)) = fold_map (collect_non_invertible_subterms ctxt) out_ts (names, []) val (out_ts'', (names'', constr_vs')) = fold_map distinct_v out_ts' ((names', map (rpair []) vs)) val mode = head_mode_of deriv val additional_arguments' = Comp_Mod.transform_additional_arguments compilation_modifiers p additional_argument val (compiled_clause, rest) = (case p of Prem t => let val u = compile_expr compilation_modifiers ctxt (t, deriv) param_modes additional_arguments' val (_, out_ts''') = split_mode mode (snd (strip_comb t)) val rest = compile_prems out_ts''' vs' names'' ps in (u, rest) end | Negprem t => let val neg_compilation_modifiers = negative_comp_modifiers_of compilation_modifiers val u = mk_not compfuns (compile_expr neg_compilation_modifiers ctxt (t, deriv) param_modes additional_arguments') val (_, out_ts''') = split_mode mode (snd (strip_comb t)) val rest = compile_prems out_ts''' vs' names'' ps in (u, rest) end | Sidecond t => let val t = compile_arg compilation_modifiers additional_arguments ctxt param_modes t val rest = compile_prems [] vs' names'' ps; in (mk_if compfuns t, rest) end | Generator (v, T) => let val u = Comp_Mod.mk_random compilation_modifiers T additional_arguments val rest = compile_prems [Free (v, T)] vs' names'' ps; in (u, rest) end) in compile_match constr_vs' eqs out_ts'' (mk_bind compfuns (compiled_clause, rest)) end val prem_t = compile_prems in_ts' (map fst param_modes) all_vs' moded_ps in mk_bind compfuns (mk_single compfuns inp, prem_t) end (* switch detection *) (** argument position of an inductive predicates and the executable functions **) type position = int * int list fun input_positions_pair Input = [[]] | input_positions_pair Output = [] | input_positions_pair (Fun _) = [] | input_positions_pair (Pair (m1, m2)) = map (cons 1) (input_positions_pair m1) @ map (cons 2) (input_positions_pair m2) fun input_positions_of_mode mode = flat (map_index (fn (i, Input) => [(i, [])] | (_, Output) => [] | (_, Fun _) => [] | (i, m as Pair _) => map (pair i) (input_positions_pair m)) (Predicate_Compile_Aux.strip_fun_mode mode)) fun argument_position_pair _ [] = [] | argument_position_pair (Pair (Fun _, m2)) (2 :: is) = argument_position_pair m2 is | argument_position_pair (Pair (m1, m2)) (i :: is) = (if eq_mode (m1, Output) andalso i = 2 then argument_position_pair m2 is else if eq_mode (m2, Output) andalso i = 1 then argument_position_pair m1 is else (i :: argument_position_pair (if i = 1 then m1 else m2) is)) fun argument_position_of mode (i, is) = (i - (length (filter (fn Output => true | Fun _ => true | _ => false) (List.take (strip_fun_mode mode, i)))), argument_position_pair (nth (strip_fun_mode mode) i) is) fun nth_pair [] t = t | nth_pair (1 :: is) (Const (\<^const_name>\<open>Pair\<close>, _) $ t1 $ _) = nth_pair is t1 | nth_pair (2 :: is) (Const (\<^const_name>\<open>Pair\<close>, _) $ _ $ t2) = nth_pair is t2 | nth_pair _ _ = raise Fail "unexpected input for nth_tuple" (** switch detection analysis **) fun find_switch_test ctxt (i, is) (ts, _) = let val t = nth_pair is (nth ts i) val T = fastype_of t in (case T of TFree _ => NONE | Type (Tcon, _) => (case Ctr_Sugar.ctr_sugar_of ctxt Tcon of NONE => NONE | SOME {ctrs, ...} => (case strip_comb t of (Var _, []) => NONE | (Free _, []) => NONE | (Const (c, T), _) => if AList.defined (op =) (map_filter (try dest_Const) ctrs) c then SOME (c, T) else NONE))) end fun partition_clause ctxt pos moded_clauses = let fun insert_list eq (key, value) = AList.map_default eq (key, []) (cons value) fun find_switch_test' moded_clause (cases, left) = (case find_switch_test ctxt pos moded_clause of SOME (c, T) => (insert_list (op =) ((c, T), moded_clause) cases, left) | NONE => (cases, moded_clause :: left)) in fold find_switch_test' moded_clauses ([], []) end datatype switch_tree = Atom of moded_clause list | Node of (position * ((string * typ) * switch_tree) list) * switch_tr fun mk_switch_tree ctxt mode moded_clauses = let fun select_best_switch moded_clauses input_position best_switch = let val ord = option_ord (rev_order o int_ord o (apply2 (length o snd o snd))) val partition = partition_clause ctxt input_position moded_clauses val switch = if (length (fst partition) > 1) then SOME (input_position, partition) else NONE in (case ord (switch, best_switch) of LESS => best_switch | EQUAL => best_switch | GREATER => switch) end fun detect_switches moded_clauses = (case fold (select_best_switch moded_clauses) (input_positions_of_mode mode) NONE of SOME (best_pos, (switched_on, left_clauses)) => Node ((best_pos, map (apsnd detect_switches) switched_on), detect_switches left_clauses) | NONE => Atom moded_clauses) in detect_switches moded_clauses end (** compilation of detected switches **) fun destruct_constructor_pattern (pat, obj) = (case strip_comb pat of (Free _, []) => cons (pat, obj) | (Const (c, T), pat_args) => (case strip_comb obj of (Const (c', T'), obj_args) => (if c = c' andalso T = T' then fold destruct_constructor_pattern (pat_args ~~ obj_args) else raise Fail "pattern and object mismatch") | _ => raise Fail "unexpected object") | _ => raise Fail "unexpected pattern") fun compile_switch compilation_modifiers ctxt all_vs param_modes additional_arguments m in_ts' outTs switch_tree = let val compfuns = Comp_Mod.compfuns compilation_modifiers val thy = Proof_Context.theory_of ctxt fun compile_switch_tree _ _ (Atom []) = NONE | compile_switch_tree all_vs ctxt_eqs (Atom moded_clauses) = let val in_ts' = map (Pattern.rewrite_term thy ctxt_eqs []) in_ts' fun compile_clause' (ts, moded_ps) = let val (ts, out_ts) = split_mode mode ts val subst = fold destruct_constructor_pattern (in_ts' ~~ ts) [] val (fsubst, pat') = List.partition (fn (_, Free _) => true | _ => false) subst val moded_ps' = (map o apfst o map_indprem) (Pattern.rewrite_term thy (map swap fsubst) []) moded_ps val inp = HOLogic.mk_tuple (map fst pat') val in_ts' = map (Pattern.rewrite_term thy (map swap fsubst) []) (map snd pat') val out_ts' = map (Pattern.rewrite_term thy (map swap fsubst) []) out_ts in compile_clause compilation_modifiers ctxt all_vs param_modes additional_arguments inp (in_ts', out_ts') moded_ps' end in SOME (foldr1 (mk_plus compfuns) (map compile_clause' moded_clauses)) end | compile_switch_tree all_vs ctxt_eqs (Node ((position, switched_clauses), left_clauses let val (i, is) = argument_position_of mode position val inp_var = nth_pair is (nth in_ts' i) val x = singleton (Name.variant_list all_vs) "x" val xt = Free (x, fastype_of inp_var) fun compile_single_case ((c, T), switched) = let val Ts = binder_types T val argnames = Name.variant_list (x :: all_vs) (map (fn i => "c" ^ string_of_int i) (1 upto length Ts)) val args = map2 (curry Free) argnames Ts val pattern = list_comb (Const (c, T), args) val ctxt_eqs' = (inp_var, pattern) :: ctxt_eqs val compilation = the_default (mk_empty compfuns (HOLogic.mk_tupleT outTs)) (compile_switch_tree (argnames @ x :: all_vs) ctxt_eqs' switched) in (pattern, compilation) end val switch = Case_Translation.make_case ctxt Case_Translation.Quiet Name.context inp_va ((map compile_single_case switched_clauses) @ [(xt, mk_empty compfuns (HOLogic.mk_tupleT outTs))]) in (case compile_switch_tree all_vs ctxt_eqs left_clauses of NONE => SOME switch | SOME left_comp => SOME (mk_plus compfuns (switch, left_comp))) end in compile_switch_tree all_vs [] switch_tree end (* compilation of predicates *) fun compile_pred options compilation_modifiers ctxt all_vs param_vs s T (pol, mode) moded_c let val is_terminating = false (* FIXME: requires an termination analysis *) val compilation_modifiers = (if pol then compilation_modifiers else negative_comp_modifiers_of compilation_modifiers) |> (if is_depth_limited_compilation (Comp_Mod.compilation compilation_modifiers) then (if is_terminating then (Comp_Mod.set_compfuns (unlimited_compfuns_of pol (Comp_Mod.compilation compilation_modifiers))) else (Comp_Mod.set_compfuns (limited_compfuns_of pol (Comp_Mod.compilation compilation_modifiers)))) else I) val additional_arguments = Comp_Mod.additional_arguments compilation_modifiers (all_vs @ param_vs) val compfuns = Comp_Mod.compfuns compilation_modifiers fun is_param_type (T as Type ("fun",[_ , T'])) = is_some (try (dest_monadT compfuns) T) orelse is_param_type T' | is_param_type T = is_some (try (dest_monadT compfuns) T) val (inpTs, outTs) = split_map_modeT (fn m => fn T => (SOME (funT_of compfuns m T), NONE)) mode (binder_types T) val funT = Comp_Mod.funT_of compilation_modifiers mode T val (in_ts, _) = fold_map (fold_map_aterms_prodT (curry HOLogic.mk_prod) (fn T => fn (param_vs, names) => if is_param_type T then (Free (hd param_vs, T), (tl param_vs, names)) else let val new = singleton (Name.variant_list names) "x" in (Free (new, T), (param_vs, new :: names)) end)) inpTs (param_vs, (all_vs @ param_vs)) val in_ts' = map_filter (map_filter_prod (fn t as Free (x, _) => if member (op =) param_vs x then NONE else SOME t | t => SOME t)) in_ts val param_modes = param_vs ~~ ho_arg_modes_of mode val compilation = if detect_switches options then the_default (mk_empty compfuns (HOLogic.mk_tupleT outTs)) (compile_switch compilation_modifiers ctxt all_vs param_modes additional_arguments mod in_ts' outTs (mk_switch_tree ctxt mode moded_cls)) else let val cl_ts = map (fn (ts, moded_prems) => compile_clause compilation_modifiers ctxt all_vs param_modes additional_arguments (HOLogic.mk_tuple in_ts') (split_mode mode ts) moded_prems) moded_cls in Comp_Mod.wrap_compilation compilation_modifiers compfuns s T mode additional_arguments (if null cl_ts then mk_empty compfuns (HOLogic.mk_tupleT outTs) else foldr1 (mk_plus compfuns) cl_ts) end val fun_const = Const (Core_Data.function_name_of (Comp_Mod.compilation compilation_modifiers) ctxt s in HOLogic.mk_Trueprop (HOLogic.mk_eq (list_comb (fun_const, in_ts @ additional_arguments), compilation)) end (* Definition of executable functions and their intro and elim rules *) fun strip_split_abs (Const (\<^const_name>\<open>case_prod\<close>, _) $ t) = strip_split_abs t | strip_split_abs (Abs (_, _, t)) = strip_split_abs t | strip_split_abs t = t fun mk_args is_eval (m as Pair (m1, m2), T as Type (\<^type_name>\<open>Product_Type.prod\<close> if eq_mode (m, Input) orelse eq_mode (m, Output) then let val x = singleton (Name.variant_list names) "x" in (Free (x, T), x :: names) end else let val (t1, names') = mk_args is_eval (m1, T1) names val (t2, names'') = mk_args is_eval (m2, T2) names' in (HOLogic.mk_prod (t1, t2), names'') end | mk_args is_eval ((m as Fun _), T) names = let val funT = funT_of Predicate_Comp_Funs.compfuns m T val x = singleton (Name.variant_list names) "x" val (args, _) = fold_map (mk_args is_eval) (strip_fun_mode m ~~ binder_types T) (x :: names) val (inargs, outargs) = split_map_mode (fn _ => fn t => (SOME t, NONE)) m args val t = fold_rev HOLogic.tupled_lambda args (Predicate_Comp_Funs.mk_Eval (list_comb (Free (x, funT), inargs), HOLogic.mk_tuple outargs)) in (if is_eval then t else Free (x, funT), x :: names) end | mk_args _ (_, T) names = let val x = singleton (Name.variant_list names) "x" in (Free (x, T), x :: names) end fun create_intro_elim_rule ctxt mode defthm mode_id funT pred = let val funtrm = Const (mode_id, funT) val Ts = binder_types (fastype_of pred) val (args, argnames) = fold_map (mk_args true) (strip_fun_mode mode ~~ Ts) [] fun strip_eval _ t = let val t' = strip_split_abs t val (r, _) = Predicate_Comp_Funs.dest_Eval t' in (SOME (fst (strip_comb r)), NONE) end val (inargs, outargs) = split_map_mode strip_eval mode args val eval_hoargs = ho_args_of mode args val hoargTs = ho_argsT_of mode Ts val hoarg_names' = Name.variant_list argnames ((map (fn i => "x" ^ string_of_int i)) (1 upto (length hoargTs))) val hoargs' = map2 (curry Free) hoarg_names' hoargTs val args' = replace_ho_args mode hoargs' args val predpropI = HOLogic.mk_Trueprop (list_comb (pred, args')) val predpropE = HOLogic.mk_Trueprop (list_comb (pred, args)) val param_eqs = map2 (HOLogic.mk_Trueprop oo (curry HOLogic.mk_eq)) eval_hoargs hoargs' val funpropE = HOLogic.mk_Trueprop (Predicate_Comp_Funs.mk_Eval (list_comb (funtrm, ina if null outargs then Free("y", HOLogic.unitT) else HOLogic.mk_tuple outargs)) val funpropI = HOLogic.mk_Trueprop (Predicate_Comp_Funs.mk_Eval (list_comb (funtrm, ina HOLogic.mk_tuple outargs)) val introtrm = Logic.list_implies (predpropI :: param_eqs, funpropI) val simprules = [defthm, @{thm pred.sel}, @{thm "split_beta"}, @{thm "fst_conv"}, @{thm "snd_conv"}, @{thm prod.collapse}] val unfolddef_tac = Simplifier.asm_full_simp_tac (put_simpset HOL_basic_ss ctxt |> Simplifier.add_simps sim val introthm = Goal.prove ctxt (argnames @ hoarg_names' @ ["y"]) [] introtrm (fn _ => unfolddef_tac) val P = HOLogic.mk_Trueprop (Free ("P", HOLogic.boolT)); val elimtrm = Logic.list_implies ([funpropE, Logic.mk_implies (predpropE, P)], P) val elimthm = Goal.prove ctxt (argnames @ ["y", "P"]) [] elimtrm (fn _ => unfolddef_tac) val opt_neg_introthm = if is_all_input mode then let val neg_predpropI = HOLogic.mk_Trueprop (HOLogic.mk_not (list_comb (pred, args'))) val neg_funpropI = HOLogic.mk_Trueprop (Predicate_Comp_Funs.mk_Eval (Predicate_Comp_Funs.mk_not (list_comb (funtrm, inargs)), HOLogic.unit)) val neg_introtrm = Logic.list_implies (neg_predpropI :: param_eqs, neg_funpropI) val tac = Simplifier.asm_full_simp_tac (put_simpset HOL_basic_ss ctxt |> Simplifier.add_simps (@{thm if_False} :: @{thm Predicate.not_pred_eq} :: simprules)) 1 THEN resolve_tac ctxt @{thms Predicate.singleI} 1 in SOME (Goal.prove ctxt (argnames @ hoarg_names') [] neg_introtrm (fn _ => tac)) end else NONE in ((introthm, elimthm), opt_neg_introthm) end fun create_constname_of_mode options thy prefix name _ mode = let val system_proposal = prefix ^ (Long_Name.base_name name) ^ "_" ^ ascii_string_of_mode mode val name = the_default system_proposal (proposed_names options name mode) in Sign.full_bname thy name end fun create_definitions options preds (name, modes) thy = let val compfuns = Predicate_Comp_Funs.compfuns val T = AList.lookup (op =) preds name |> the fun create_definition mode thy = let val mode_cname = create_constname_of_mode options thy "" name T mode val mode_cbasename = Long_Name.base_name mode_cname val funT = funT_of compfuns mode T val (args, _) = fold_map (mk_args true) (strip_fun_mode mode ~~ binder_types T) [] fun strip_eval _ t = let val t' = strip_split_abs t val (r, _) = Predicate_Comp_Funs.dest_Eval t' in (SOME (fst (strip_comb r)), NONE) end val (inargs, outargs) = split_map_mode strip_eval mode args val predterm = fold_rev HOLogic.tupled_lambda inargs (Predicate_Comp_Funs.mk_Enum (HOLogic.tupled_lambda (HOLogic.mk_tuple outargs) (list_comb (Const (name, T), args)))) val lhs = Const (mode_cname, funT) val def = Logic.mk_equals (lhs, predterm) val (definition, thy') = thy |> Sign.add_consts [(Binding.name mode_cbasename, funT, NoSyn)] |> Global_Theory.add_def (Binding.name (Thm.def_name mode_cbasename), def) val ctxt' = Proof_Context.init_global thy' val rules as ((intro, elim), _) = create_intro_elim_rule ctxt' mode definition mode_cname funT (Const (name, T)) in thy' |> Core_Data.set_function_name Pred name mode mode_cname |> Core_Data.add_predfun_data name mode (definition, rules) |> Global_Theory.store_thm (Binding.name (mode_cbasename ^ "I"), intro) |> snd |> Global_Theory.store_thm (Binding.name (mode_cbasename ^ "E"), elim) |> snd end; in thy |> Core_Data.defined_function_of Pred name |> fold create_definition modes end; fun define_functions comp_modifiers _ options preds (name, modes) thy = let val T = AList.lookup (op =) preds name |> the fun create_definition mode thy = let val function_name_prefix = Comp_Mod.function_name_prefix comp_modifiers val mode_cname = create_constname_of_mode options thy function_name_prefix name T mode val funT = Comp_Mod.funT_of comp_modifiers mode T in thy |> Sign.add_consts [(Binding.name (Long_Name.base_name mode_cname), funT, NoSyn)] |> Core_Data.set_function_name (Comp_Mod.compilation comp_modifiers) name mode mode_cna end; in thy |> Core_Data.defined_function_of (Comp_Mod.compilation comp_modifiers) name |> fold create_definition modes end; (* composition of mode inference, definition, compilation and proof *) (** auxillary combinators for table of preds and modes **) fun map_preds_modes f preds_modes_table = map (fn (pred, modes) => (pred, map (fn (mode, value) => (mode, f pred mode value)) modes)) preds_modes_table fun join_preds_modes table1 table2 = map_preds_modes (fn pred => fn mode => fn value => (value, the (AList.lookup (op =) (the (AList.lookup (op =) table2 pred)) mode))) table1 fun maps_modes preds_modes_table = map (fn (pred, modes) => (pred, map (fn (_, value) => value) modes)) preds_modes_table fun compile_preds options comp_modifiers ctxt all_vs param_vs preds moded_clauses = map_preds_modes (fn pred => compile_pred options comp_modifiers ctxt all_vs param_vs pred (the (AList.lookup (op =) preds pred))) moded_clauses fun prove options thy clauses preds moded_clauses compiled_terms = map_preds_modes (prove_pred options thy clauses preds) (join_preds_modes moded_clauses compiled_terms) fun prove_by_skip _ thy _ _ _ compiled_terms = map_preds_modes (fn _ => fn _ => fn t => Drule.export_without_context (Skip_Proof.make_thm thy t)) compiled_terms (* preparation of introduction rules into special datastructures *) fun dest_prem ctxt params t = (case strip_comb t of (v as Free _, _) => if member (op =) params v then Prem t else Sidecond t | (c as Const (\<^const_name>\<open>Not\<close>, _), [t]) => (case dest_prem ctxt params t of Prem t => Negprem t | Negprem _ => error ("Double negation not allowed in premise: " ^ Syntax.string_of_term ctxt (c $ t)) | Sidecond t => Sidecond (c $ t)) | (Const (s, _), _) => if Core_Data.is_registered ctxt s then Prem t else Sidecond t | _ => Sidecond t) fun prepare_intrs options ctxt prednames intros = let val thy = Proof_Context.theory_of ctxt val intrs = map Thm.prop_of intros val preds = map (fn c => Const (c, Sign.the_const_type thy c)) prednames val (preds, intrs) = unify_consts thy preds intrs val ([preds, intrs], _) = fold_burrow (Variable.import_terms false) [preds, intrs] ctxt val preds = map dest_Const preds val all_vs = terms_vs intrs fun generate_modes s T = if member (op =) (no_higher_order_predicate options) s then all_smodes_of_typ T else all_modes_of_typ T val all_modes = map (fn (s, T) => (s, (case proposed_modes options s of SOME ms => check_matches_type ctxt s T ms | NONE => generate_modes s T))) preds val params = (case intrs of [] => let val T = snd (hd preds) val one_mode = hd (the (AList.lookup (op =) all_modes (fst (hd preds)))) val paramTs = ho_argsT_of one_mode (binder_types T) val param_names = Name.variant_list [] (map (fn i => "p" ^ string_of_int i) (1 upto length paramTs)) in map2 (curry Free) param_names paramTs end | (intr :: _) => let val (p, args) = strip_comb (HOLogic.dest_Trueprop (Logic.strip_imp_concl intr)) val one_mode = hd (the (AList.lookup (op =) all_modes (dest_Const_name p))) in ho_args_of one_mode args end) val param_vs = map (fst o dest_Free) params fun add_clause intr clauses = let val (Const (name, _), ts) = strip_comb (HOLogic.dest_Trueprop (Logic.strip_imp_concl intr)) val prems = map (dest_prem ctxt params o HOLogic.dest_Trueprop) (Logic.strip_imp_prems intr) in AList.update op = (name, these (AList.lookup op = clauses name) @ [(ts, prems)]) clauses end; val clauses = fold add_clause intrs [] in (preds, all_vs, param_vs, all_modes, clauses) end (* sanity check of introduction rules *) (* TODO: rethink check with new modes *) (* fun check_format_of_intro_rule thy intro = let val concl = Logic.strip_imp_concl (prop_of intro) val (p, args) = strip_comb (HOLogic.dest_Trueprop concl) val params = fst (chop (nparams_of thy (dest_Const_name p)) args) fun check_arg arg = case HOLogic.strip_tupleT (fastype_of arg) of (Ts as _ :: _ :: _) => if length (HOLogic.strip_tuple arg) = length Ts then true else error ("Format of introduction rule is invalid: tuples must be expanded:" ^ (Syntax.string_of_term_global thy arg) ^ " in " ^ (Thm.string_of_thm_global thy intro)) | _ => true val prems = Logic.strip_imp_prems (prop_of intro) fun check_prem (Prem t) = forall check_arg args | check_prem (Negprem t) = forall check_arg args | check_prem _ = true in forall check_arg args andalso forall (check_prem o dest_prem thy params o HOLogic.dest_Trueprop) prems end *) (* fun check_intros_elim_match thy prednames = let fun check predname = let val intros = intros_of thy predname val elim = the_elim_of thy predname val nparams = nparams_of thy predname val elim' = (Drule.export_without_context o Skip_Proof.make_thm thy) (mk_casesrule (Proof_Context.init_global thy) nparams intros) in if not (Thm.equiv_thm (elim, elim')) then error "Introduction and elimination rules do not match!" else true end in forall check prednames end *) (* create code equation *) fun add_code_equations ctxt preds result_thmss = let fun add_code_equation (predname, T) (pred, result_thms) = let val full_mode = fold_rev (curry Fun) (map (K Input) (binder_types T)) Bool in if member eq_mode (Core_Data.modes_of Pred ctxt predname) full_mode then let val Ts = binder_types T val arg_names = Name.variant_list [] (map (fn i => "x" ^ string_of_int i) (1 upto length Ts)) val args = map2 (curry Free) arg_names Ts val predfun = Const (Core_Data.function_name_of Pred ctxt predname full_mode, Ts ---> Predicate_Comp_Funs.mk_monadT \<^typ>\<open>unit\<close>) val rhs = \<^term>\<open>Predicate.holds\<close> $ (list_comb (predfun, args)) val eq_term = HOLogic.mk_Trueprop (HOLogic.mk_eq (list_comb (Const (predname, T), args), rhs)) val def = Core_Data.predfun_definition_of ctxt predname full_mode val tac = fn _ => Simplifier.simp_tac (put_simpset HOL_basic_ss ctxt |> Simplifier.add_simps [def, @{thm holds_eq}, @{thm pred.sel}]) 1 val eq = Goal.prove ctxt arg_names [] eq_term tac in (pred, result_thms @ [eq]) end else (pred, result_thms) end in map2 add_code_equation preds result_thmss end (** main function of predicate compiler **) datatype steps = Steps of { define_functions : options -> (string * typ) list -> string * (bool * mode) list -> theory -> theory, prove : options -> theory -> (string * (term list * indprem list) list) list -> (string * typ) list -> moded_clause list pred_mode_table -> term pred_mode_table -> thm pred_mode_table, add_code_equations : Proof.context -> (string * typ) list -> (string * thm list) list -> (string * thm list) list, comp_modifiers : Comp_Mod.comp_modifiers, use_generators : bool, qname : bstring } fun add_equations_of steps mode_analysis_options options prednames thy = let fun dest_steps (Steps s) = s val compilation = Comp_Mod.compilation (#comp_modifiers (dest_steps steps)) val ctxt = Proof_Context.init_global thy val _ = print_step options ("Starting predicate compiler (compilation: " ^ string_of_compilation compilation ^ ") for predicates " ^ commas prednames ^ "...") (*val _ = check_intros_elim_match thy prednames*) (*val _ = map (check_format_of_intro_rule thy) (maps (intros_of thy) prednames)*) val _ = if show_intermediate_results options then tracing (commas (map (Thm.string_of_thm ctxt) (maps (Core_Data.intros_of ctxt) prednames else () val (preds, all_vs, param_vs, all_modes, clauses) = prepare_intrs options ctxt prednames (maps (Core_Data.intros_of ctxt) prednames) val _ = print_step options "Infering modes..." val (lookup_mode, lookup_neg_mode, needs_random) = (Core_Data.modes_of compilation ctxt Core_Data.modes_of (negative_compilation_of compilation) ctxt, Core_Data.needs_rando val ((moded_clauses, needs_random), errors) = cond_timeit (Config.get ctxt Quickcheck.timing) "Infering modes" (fn _ => infer_modes mode_analysis_options options (lookup_mode, lookup_neg_mode, needs_random) ctxt preds all_modes param_vs claus val thy' = fold (fn (s, ms) => Core_Data.set_needs_random s ms) needs_random thy val modes = map (fn (p, mps) => (p, map fst mps)) moded_clauses val _ = check_expected_modes options preds modes val _ = check_proposed_modes options preds modes errors val _ = print_modes options modes val _ = print_step options "Defining executable functions..." val thy'' = cond_timeit (Config.get ctxt Quickcheck.timing) "Defining executable functions..." (fn _ => fold (#define_functions (dest_steps steps) options preds) modes thy') val ctxt'' = Proof_Context.init_global thy'' val _ = print_step options "Compiling equations..." val compiled_terms = cond_timeit (Config.get ctxt Quickcheck.timing) "Compiling equations...." (fn _ => compile_preds options (#comp_modifiers (dest_steps steps)) ctxt'' all_vs param_vs preds moded_clauses) val _ = print_compiled_terms options ctxt'' compiled_terms val _ = print_step options "Proving equations..." val result_thms = cond_timeit (Config.get ctxt Quickcheck.timing) "Proving equations...." (fn _ => #prove (dest_steps steps) options thy'' clauses preds moded_clauses compiled_terms) val result_thms' = #add_code_equations (dest_steps steps) ctxt'' preds (maps_modes result_thms) val qname = #qname (dest_steps steps) val thy''' = cond_timeit (Config.get ctxt Quickcheck.timing) "Setting code equations...." (fn _ => thy'' |> fold_map (fn (name, result_thms) => (Global_Theory.add_thmss [((Binding.qualify true (Long_Name.base_name name) (Binding.name qname), result_thms), result_thms' |-> (fn notes => Code.declare_default_eqns_global (map (rpair true) ((flat o flat) notes)))) in thy''' end fun gen_add_equations steps options names thy = let fun dest_steps (Steps s) = s val defined = Core_Data.defined_functions (Comp_Mod.compilation (#comp_modifiers (dest val thy' = Core_Data.extend_intro_graph names thy; fun strong_conn_of gr keys = Graph.strong_conn (Graph.restrict (member (op =) (Graph.all_succs gr keys)) gr) val scc = strong_conn_of (Core_Data.PredData.get thy') names val thy'' = fold Core_Data.preprocess_intros (flat scc) thy' val thy''' = fold_rev (fn preds => fn thy => if not (forall (defined (Proof_Context.init_global thy)) preds) then let val mode_analysis_options = {use_generators = #use_generators (dest_steps steps), reorder_premises = not (no_topmost_reordering options andalso not (null (inter (op =) preds names))), infer_pos_and_neg_modes = #use_generators (dest_steps steps)} in add_equations_of steps mode_analysis_options options preds thy end else thy) scc thy'' in thy''' end val add_equations = gen_add_equations (Steps { define_functions = fn options => fn preds => fn (s, modes) => create_definitions options preds (s, map_filter (fn (true, m) => SOME m | _ => NONE) modes), prove = prove, add_code_equations = add_code_equations, comp_modifiers = predicate_comp_modifiers, use_generators = false, qname = "equation"}) val add_depth_limited_equations = gen_add_equations (Steps { define_functions = fn options => fn preds => fn (s, modes) => define_functions depth_limited_comp_modifiers Predicate_Comp_Funs.compfuns options preds (s, map_filter (fn (true, m) => SOME m | _ => NONE) modes), prove = prove_by_skip, add_code_equations = K (K I), comp_modifiers = depth_limited_comp_modifiers, use_generators = false, qname = "depth_limited_equation"}) val add_random_equations = gen_add_equations (Steps { define_functions = fn options => fn preds => fn (s, modes) => define_functions random_comp_modifiers Predicate_Comp_Funs.compfuns options preds (s, map_filter (fn (true, m) => SOME m | _ => NONE) modes), comp_modifiers = random_comp_modifiers, prove = prove_by_skip, add_code_equations = K (K I), use_generators = true, qname = "random_equation"}) val add_depth_limited_random_equations = gen_add_equations (Steps { define_functions = fn options => fn preds => fn (s, modes) => define_functions depth_limited_random_comp_modifiers Predicate_Comp_Funs.compfuns o (s, map_filter (fn (true, m) => SOME m | _ => NONE) modes), comp_modifiers = depth_limited_random_comp_modifiers, prove = prove_by_skip, add_code_equations = K (K I), use_generators = true, qname = "depth_limited_random_equation"}) val add_dseq_equations = gen_add_equations (Steps { define_functions = fn options => fn preds => fn (s, modes) => define_functions dseq_comp_modifiers DSequence_CompFuns.compfuns options preds (s, map_filter (fn (true, m) => SOME m | _ => NONE) modes), prove = prove_by_skip, add_code_equations = K (K I), comp_modifiers = dseq_comp_modifiers, use_generators = false, qname = "dseq_equation"}) val add_random_dseq_equations = gen_add_equations (Steps { define_functions = fn options => fn preds => fn (s, modes) => let val pos_modes = map_filter (fn (true, m) => SOME m | _ => NONE) modes val neg_modes = map_filter (fn (false, m) => SOME m | _ => NONE) modes in define_functions pos_random_dseq_comp_modifiers Random_Sequence_CompFuns.compfun options preds (s, pos_modes) #> define_functions neg_random_dseq_comp_modifiers Random_Sequence_CompFuns.compfuns options preds (s, neg_modes) end, prove = prove_by_skip, add_code_equations = K (K I), comp_modifiers = pos_random_dseq_comp_modifiers, use_generators = true, qname = "random_dseq_equation"}) val add_new_random_dseq_equations = gen_add_equations (Steps { define_functions = fn options => fn preds => fn (s, modes) => let val pos_modes = map_filter (fn (true, m) => SOME m | _ => NONE) modes val neg_modes = map_filter (fn (false, m) => SOME m | _ => NONE) modes in define_functions new_pos_random_dseq_comp_modifiers New_Pos_Random_Sequence_CompFuns.depth_limited_compfuns options preds (s, pos_modes) #> define_functions new_neg_random_dseq_comp_modifiers New_Neg_Random_Sequence_CompFuns.depth_limited_compfuns options preds (s, neg_modes) end, prove = prove_by_skip, add_code_equations = K (K I), comp_modifiers = new_pos_random_dseq_comp_modifiers, use_generators = true, qname = "new_random_dseq_equation"}) val add_generator_dseq_equations = gen_add_equations (Steps { define_functions = fn options => fn preds => fn (s, modes) => let val pos_modes = map_filter (fn (true, m) => SOME m | _ => NONE) modes val neg_modes = map_filter (fn (false, m) => SOME m | _ => NONE) modes in define_functions pos_generator_dseq_comp_modifiers New_Pos_DSequence_CompFuns.depth_limited_compfuns options preds (s, pos_modes) #> define_functions neg_generator_dseq_comp_modifiers New_Neg_DSequence_CompFuns.depth_limited_compfuns options preds (s, neg_modes) end, prove = prove_by_skip, add_code_equations = K (K I), comp_modifiers = pos_generator_dseq_comp_modifiers, use_generators = true, qname = "generator_dseq_equation"}) val add_generator_cps_equations = gen_add_equations (Steps { define_functions = fn options => fn preds => fn (s, modes) => let val pos_modes = map_filter (fn (true, m) => SOME m | _ => NONE) modes val neg_modes = map_filter (fn (false, m) => SOME m | _ => NONE) modes in define_functions pos_generator_cps_comp_modifiers Pos_Bounded_CPS_Comp_Funs.compfu options preds (s, pos_modes) #> define_functions neg_generator_cps_comp_modifiers Neg_Bounded_CPS_Comp_Funs.compf options preds (s, neg_modes) end, prove = prove_by_skip, add_code_equations = K (K I), comp_modifiers = pos_generator_cps_comp_modifiers, use_generators = true, qname = "generator_cps_equation"}) (** user interface **) (* code_pred_intro attribute *) fun attrib' f opt_case_name = Thm.declaration_attribute (fn thm => Context.mapping (f (opt_case_name, thm)) I); val code_pred_intro_attrib = attrib' Core_Data.add_intro NONE; (*FIXME - Naming of auxiliary rules necessary? *) (* values_timeout configuration *) val values_timeout = Attrib.setup_config_real \<^binding>\<open>values_timeout\<close> (K 40.0) val _ = Theory.setup (Core_Data.PredData.put (Graph.empty) #> Attrib.setup \<^binding>\<open>code_pred_intro\<close> (Scan.lift (Scan.option Args.name) >> attrib' Core_Data.add_intro) "adding alternative introduction rules for code generation of inductive predicates") (* TODO: make Theory_Data to Generic_Data & remove duplication of local theory and theory (* FIXME ... this is important to avoid changing the background theory below *) fun generic_code_pred prep_const options raw_const lthy = let val const = prep_const lthy raw_const val lthy' = Local_Theory.background_theory (Core_Data.extend_intro_graph [const]) lthy val thy' = Proof_Context.theory_of lthy' val ctxt' = Proof_Context.init_global thy' val preds = Graph.all_succs (Core_Data.PredData.get thy') [const] |> filter_out (Core_Data.has_elim fun mk_cases const = let val T = Sign.the_const_type thy' const val pred = Const (const, T) val intros = Core_Data.intros_of ctxt' const in mk_casesrule lthy' pred intros end val cases_rules = map mk_cases preds val cases = map2 (fn pred_name => fn case_rule => Rule_Cases.Case { fixes = [], assumes = ("that", tl (Logic.strip_imp_prems case_rule)) :: map_filter (fn (fact_name, fact) => Option.map (fn a => (a, [fact])) fact_name) ((SOME "prems" :: Core_Data.names_of ctxt' pred_name) ~~ Logic.strip_imp_prems case_rule binds = [], cases = []}) preds cases_rules val case_env = map2 (fn p => fn c => (Long_Name.base_name p, SOME c)) preds cases val lthy'' = lthy' |> fold Proof_Context.augment cases_rules |> Proof_Context.update_cases case_env fun after_qed thms goal_ctxt = let val global_thms = Proof_Context.export goal_ctxt (Proof_Context.init_global (Proof_Context.theory_of goal_ctxt)) (map the_single thms) in goal_ctxt |> Local_Theory.background_theory (fold Core_Data.set_elim global_thms #> ((case compilation options of Pred => add_equations | DSeq => add_dseq_equations | Pos_Random_DSeq => add_random_dseq_equations | Depth_Limited => add_depth_limited_equations | Random => add_random_equations | Depth_Limited_Random => add_depth_limited_random_equations | New_Pos_Random_DSeq => add_new_random_dseq_equations | Pos_Generator_DSeq => add_generator_dseq_equations | Pos_Generator_CPS => add_generator_cps_equations | _ => error ("Compilation not supported") ) options [const])) end in Proof.theorem NONE after_qed (map (single o (rpair [])) cases_rules) lthy'' end; val code_pred = generic_code_pred (K I); val code_pred_cmd = generic_code_pred Code.read_const (* transformation for code generation *) structure Data = Proof_Data ( type T = (unit -> term Predicate.pred) * (unit -> seed -> term Predicate.pred * seed) * (unit -> term Limited_Sequence.dseq) * (unit -> Code_Numeral.natural -> Code_Numeral.natural -> seed -> term Limited_Sequence.dseq * seed) * (unit -> Code_Numeral.natural -> term Lazy_Sequence.lazy_sequence) * (unit -> Code_Numeral.natural -> Code_Numeral.natural -> seed -> Code_Numeral.natural -> term Lazy_Sequence.lazy_sequence) * (unit -> Code_Numeral.natural -> Code_Numeral.natural -> seed -> Code_Numeral.natural -> (term * Code_Numeral.natural) Lazy_Sequence.lazy_sequence); val empty: T = (fn () => raise Fail "pred_result", fn () => raise Fail "pred_random_result", fn () => raise Fail "dseq_result", fn () => raise Fail "dseq_random_result", fn () => raise Fail "new_dseq_result", fn () => raise Fail "lseq_random_result", fn () => raise Fail "lseq_random_stats_result"); fun init _ = empty; ); val get_pred_result = #1 o Data.get; val get_pred_random_result = #2 o Data.get; val get_dseq_result = #3 o Data.get; val get_dseq_random_result = #4 o Data.get; val get_new_dseq_result = #5 o Data.get; val get_lseq_random_result = #6 o Data.get; val get_lseq_random_stats_result = #7 o Data.get; val put_pred_result = Data.map o @{apply 7(1)} o K; val put_pred_random_result = Data.map o @{apply 7(2)} o K; val put_dseq_result = Data.map o @{apply 7(3)} o K; val put_dseq_random_result = Data.map o @{apply 7(4)} o K; val put_new_dseq_result = Data.map o @{apply 7(5)} o K; val put_lseq_random_result = Data.map o @{apply 7(6)} o K; val put_lseq_random_stats_result = Data.map o @{apply 7(7)} o K; fun dest_special_compr t = let val (inner_t, T_compr) = (case t of (Const (\<^const_name>\<open>Collect\<close>, _) $ Abs (_, T, t)) => (t, T) | _ => raise TERM ("dest_special_compr", [t])) val (Ts, conj) = apfst (map snd) (Predicate_Compile_Aux.strip_ex inner_t) val [eq, body] = HOLogic.dest_conj conj val rhs = (case HOLogic.dest_eq eq of (Bound i, rhs) => if i = length Ts then rhs else raise TERM ("dest_special_compr", [t]) | _ => raise TERM ("dest_special_compr", [t])) val output_names = Name.variant_list (fold Term.add_free_names [rhs, body] []) (map (fn i => "x" ^ string_of_int i) (1 upto length Ts)) val output_frees = map2 (curry Free) output_names (rev Ts) val body = subst_bounds (output_frees, body) val output = subst_bounds (output_frees, rhs) in (((body, output), T_compr), output_names) end fun dest_general_compr ctxt t_compr = let val inner_t = (case t_compr of (Const (\<^const_name>\<open>Collect\<close>, _) $ t) => t | _ => error ("Not a set comprehension: " ^ Syntax.string_of_term ctxt t_compr)) val (body, Ts, fp) = HOLogic.strip_ptupleabs inner_t; val output_names = Name.variant_list (Term.add_free_names body []) (map (fn i => "x" ^ string_of_int i) (1 upto length Ts)) val output_frees = map2 (curry Free) output_names (rev Ts) val body = subst_bounds (output_frees, body) val T_compr = HOLogic.mk_ptupleT fp Ts val output = HOLogic.mk_ptuple fp T_compr (rev output_frees) in (((body, output), T_compr), output_names) end (*FIXME turn this into an LCF-guarded preprocessor for comprehensions*) fun analyze_compr ctxt (comp_modifiers, additional_arguments) param_user_modes (compilation, _) t_compr = let val compfuns = Comp_Mod.compfuns comp_modifiers val all_modes_of = Core_Data.all_modes_of compilation val (((body, output), T_compr), output_names) = (case try dest_special_compr t_compr of SOME r => r | NONE => dest_general_compr ctxt t_compr) val (Const (name, _), all_args) = (case strip_comb body of (Const (name, T), all_args) => (Const (name, T), all_args) | (head, _) => error ("Not a constant: " ^ Syntax.string_of_term ctxt head)) in if Core_Data.defined_functions compilation ctxt name then let fun extract_mode (Const (\<^const_name>\<open>Pair\<close>, _) $ t1 $ t2) = Pair (extract_mode t1, extract_mode t2) | extract_mode (Free (x, _)) = if member (op =) output_names x then Output else Input | extract_mode _ = Input val user_mode = fold_rev (curry Fun) (map extract_mode all_args) Bool fun valid modes1 modes2 = (case int_ord (length modes1, length modes2) of GREATER => error "Not enough mode annotations" | LESS => error "Too many mode annotations" | EQUAL => forall (fn (_, NONE) => true | (m, SOME m2) => eq_mode (m, m2)) (modes1 ~~ modes2)) fun mode_instance_of (m1, m2) = let fun instance_of (Fun _, Input) = true | instance_of (Input, Input) = true | instance_of (Output, Output) = true | instance_of (Pair (m1, m2), Pair (m1', m2')) = instance_of (m1, m1') andalso instance_of (m2, m2') | instance_of (Pair (m1, m2), Input) = instance_of (m1, Input) andalso instance_of (m2, Input) | instance_of (Pair (m1, m2), Output) = instance_of (m1, Output) andalso instance_of (m2, Output) | instance_of (Input, Pair (m1, m2)) = instance_of (Input, m1) andalso instance_of (Input, m2) | instance_of (Output, Pair (m1, m2)) = instance_of (Output, m1) andalso instance_of (Output, m2) | instance_of _ = false in forall instance_of (strip_fun_mode m1 ~~ strip_fun_mode m2) end val derivs = all_derivations_of ctxt (all_modes_of ctxt) [] body |> filter (fn (d, missing_vars) => let val (p_mode :: modes) = collect_context_modes d in null missing_vars andalso mode_instance_of (p_mode, user_mode) andalso the_default true (Option.map (valid modes) param_user_modes) end) |> map fst val deriv = (case derivs of [] => error ("No mode possible for comprehension " ^ Syntax.string_of_term ctxt t_compr) | [d] => d | d :: _ :: _ => (warning ("Multiple modes possible for comprehension " ^ Syntax.string_of_term ctxt t_compr); d)) val (_, outargs) = split_mode (head_mode_of deriv) all_args val t_pred = compile_expr comp_modifiers ctxt (body, deriv) [] additional_arguments; val T_pred = dest_monadT compfuns (fastype_of t_pred) val arrange = HOLogic.tupled_lambda (HOLogic.mk_tuple outargs) output in if null outargs then t_pred else mk_map compfuns T_pred T_compr arrange t_pred end else error "Evaluation with values is not possible because compilation with code_pred was not invo end fun eval ctxt stats param_user_modes (options as (compilation, arguments)) k t_compr = let fun count xs x = let fun count' i [] = i | count' i (x' :: xs) = if x = x' then count' (i + 1) xs else count' i xs in count' 0 xs end fun accumulate xs = (map (fn x => (x, count xs x)) o sort int_ord o distinct (op =)) xs; val comp_modifiers = (case compilation of Pred => predicate_comp_modifiers | Random => random_comp_modifiers | Depth_Limited => depth_limited_comp_modifiers | Depth_Limited_Random => depth_limited_random_comp_modifiers (*| Annotated => annotated_comp_modifiers*) | DSeq => dseq_comp_modifiers | Pos_Random_DSeq => pos_random_dseq_comp_modifiers | New_Pos_Random_DSeq => new_pos_random_dseq_comp_modifiers | Pos_Generator_DSeq => pos_generator_dseq_comp_modifiers) val compfuns = Comp_Mod.compfuns comp_modifiers val additional_arguments = (case compilation of Pred => [] | Random => map (HOLogic.mk_number \<^typ>\<open>natural\<close>) arguments @ [\<^term>\<open>(1, 1) :: natural * natural\<close>] | Annotated => [] | Depth_Limited => [HOLogic.mk_number \<^typ>\<open>natural\<close> (hd arguments)] | Depth_Limited_Random => map (HOLogic.mk_number \<^typ>\<open>natural\<close>) arguments @ [\<^term>\<open>(1, 1) :: natural * natural\<close>] | DSeq => [] | Pos_Random_DSeq => [] | New_Pos_Random_DSeq => [] | Pos_Generator_DSeq => []) val t = analyze_compr ctxt (comp_modifiers, additional_arguments) param_user_modes options t_c val T = dest_monadT compfuns (fastype_of t) val t' = if stats andalso compilation = New_Pos_Random_DSeq then mk_map compfuns T (HOLogic.mk_prodT (HOLogic.termT, \<^typ>\<open>natural\<close>)) (absdummy T (HOLogic.mk_prod (HOLogic.term_of_const T $ Bound 0, \<^term>\<open>natural_of_nat\<close> $ (HOLogic.size_const T $ Bound 0)))) t else mk_map compfuns T HOLogic.termT (HOLogic.term_of_const T) t val time_limit = seconds (Config.get ctxt values_timeout) val (ts, statistics) = (case compilation of (* Random => fst (Predicate.yieldn k (Code_Eval.eval NONE ("Predicate_Compile_Core.random_eval_ref", random_eval_ref) (fn proc => fn g => fn s => g s |>> Predicate.map proc) thy t' [] |> Random_Engine.run))*) Pos_Random_DSeq => let val [nrandom, size, depth] = map Code_Numeral.natural_of_integer arguments in rpair NONE (Timeout.apply time_limit (fn () => fst (Limited_Sequence.yieldn k (Code_Runtime.dynamic_value_strict (get_dseq_random_result, put_dseq_random_result, "Predicate_Compile_Core.put_dseq_random_result") ctxt NONE (fn proc => fn g => fn nrandom => fn size => fn s => g nrandom size s |>> Limited_Sequence.map proc) t' [] nrandom size |> Random_Engine.run) depth true)) ()) end | DSeq => rpair NONE (Timeout.apply time_limit (fn () => fst (Limited_Sequence.yieldn k (Code_Runtime.dynamic_value_strict (get_dseq_result, put_dseq_result, "Predicate_Compile_Core.put_dseq_result") ctxt NONE Limited_Sequence.map t' []) (Code_Numeral.natural_of_integer (the_single arguments)) true)) ()) | Pos_Generator_DSeq => let val depth = Code_Numeral.natural_of_integer (the_single arguments) in rpair NONE (Timeout.apply time_limit (fn () => fst (Lazy_Sequence.yieldn k (Code_Runtime.dynamic_value_strict (get_new_dseq_result, put_new_dseq_result, "Predicate_Compile_Core.put_new_dseq_result") ctxt NONE (fn proc => fn g => fn depth => g depth |> Lazy_Sequence.map proc) t' [] depth))) ()) end | New_Pos_Random_DSeq => let val [nrandom, size, depth] = map Code_Numeral.natural_of_integer arguments val seed = Random_Engine.next_seed () in if stats then apsnd (SOME o accumulate o map Code_Numeral.integer_of_natural) (split_list (Timeout.apply time_limit (fn () => fst (Lazy_Sequence.yieldn k (Code_Runtime.dynamic_value_strict (get_lseq_random_stats_result, put_lseq_random_stats_result, "Predicate_Compile_Core.put_lseq_random_stats_result") ctxt NONE (fn proc => fn g => fn nrandom => fn size => fn s => fn depth => g nrandom size s depth |> Lazy_Sequence.map (apfst proc)) t' [] nrandom size seed depth))) ())) else rpair NONE (Timeout.apply time_limit (fn () => fst (Lazy_Sequence.yieldn k (Code_Runtime.dynamic_value_strict (get_lseq_random_result, put_lseq_random_result, "Predicate_Compile_Core.put_lseq_random_result") ctxt NONE (fn proc => fn g => fn nrandom => fn size => fn s => fn depth => g nrandom size s depth |> Lazy_Sequence.map proc) t' [] nrandom size seed depth))) ()) end | _ => rpair NONE (Timeout.apply time_limit (fn () => fst (Predicate.yieldn k (Code_Runtime.dynamic_value_strict (get_pred_result, put_pred_result, "Predicate_Compile_Core.put_pred_result") ctxt NONE Predicate.map t' []))) ())) handle Timeout.TIMEOUT _ => error "Reached timeout during execution of values" in ((T, ts), statistics) end; fun values param_user_modes ((raw_expected, stats), comp_options) k t_compr ctxt = let val ((T, ts), statistics) = eval ctxt stats param_user_modes comp_options k t_compr val setT = HOLogic.mk_setT T val elems = HOLogic.mk_set T ts val ([dots], ctxt') = ctxt |> Proof_Context.add_fixes [(Binding.name "dots", SOME setT, Mixfix.mixfix "...")] (* check expected values *) val union = Const (\<^const_abbrev>\<open>Set.union\<close>, setT --> setT --> setT) val () = (case raw_expected of NONE => () | SOME s => if eq_set (op =) (HOLogic.dest_set (Syntax.read_term ctxt s), ts) then () else error ("expected and computed values do not match:\n" ^ "expected values: " ^ Syntax.string_of_term ctxt (Syntax.read_term ctxt s) ^ "\n" ^ "computed values: " ^ Syntax.string_of_term ctxt elems ^ "\n")) in ((if k = ~1 orelse length ts < k then elems else union $ elems $ Free (dots, setT), statistics), ctxt') end; fun values_cmd print_modes param_user_modes options k raw_t state = let val ctxt = Toplevel.context_of state val t = Syntax.read_term ctxt raw_t val ((t', stats), ctxt') = values param_user_modes options k t ctxt val ty' = Term.type_of t' val ctxt'' = Proof_Context.augment t' ctxt' val pretty_stat = (case stats of NONE => [] | SOME xs => let val total = fold (curry (op +)) (map snd xs) 0 fun pretty_entry (s, n) = [Pretty.str "size", Pretty.brk 1, Pretty.str (string_of_int s), Pretty.str ":", Pretty.brk 1, Pretty.str (string_of_int n), Pretty.fbrk] in [Pretty.fbrk, Pretty.str "Statistics:", Pretty.fbrk, Pretty.str "total:", Pretty.brk 1, Pretty.str (string_of_int total), Pretty.fbrk] @ maps pretty_entry xs end) in Print_Mode.with_modes print_modes (fn () => Pretty.block ([Pretty.quote (Syntax.pretty_term ctxt'' t'), Pretty.fbrk, Pretty.str "::", Pretty.brk 1, Pretty.quote (Syntax.pretty_typ ctxt'' ty')] @ pretty_stat)) () end |> Pretty.writeln end
¤ Dauer der Verarbeitung: 0.30 Sekunden (vorverarbeitet am 2026-04-26) ¤*© Formatika GbR, Deutschland |
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2026-05-26