src/HOL/Tools/Predicate_Compile/predicate_compile_aux.ML
author bulwahn
Thu Oct 21 19:13:11 2010 +0200 (2010-10-21)
changeset 40054 cd7b1fa20bce
parent 40052 ea46574ca815
child 40101 f7fc517e21c6
permissions -rw-r--r--
adapting alternative_defs, predicate_compile_quickcheck, examples and code_prolog
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(*  Title:      HOL/Tools/Predicate_Compile/predicate_compile_aux.ML
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    Author:     Lukas Bulwahn, TU Muenchen
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Auxilary functions for predicate compiler.
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*)
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signature PREDICATE_COMPILE_AUX =
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sig
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  (* general functions *)
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  val apfst3 : ('a -> 'd) -> 'a * 'b * 'c -> 'd * 'b * 'c
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  val apsnd3 : ('b -> 'd) -> 'a * 'b * 'c -> 'a * 'd * 'c
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  val aptrd3 : ('c -> 'd) -> 'a * 'b * 'c -> 'a * 'b * 'd
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  val find_indices : ('a -> bool) -> 'a list -> int list
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  val assert : bool -> unit
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  (* mode *)
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  datatype mode = Bool | Input | Output | Pair of mode * mode | Fun of mode * mode
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  val eq_mode : mode * mode -> bool
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  val mode_ord: mode * mode -> order
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  val list_fun_mode : mode list -> mode
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  val strip_fun_mode : mode -> mode list
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  val dest_fun_mode : mode -> mode list
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  val dest_tuple_mode : mode -> mode list
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  val all_modes_of_typ : typ -> mode list
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  val all_smodes_of_typ : typ -> mode list
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  val fold_map_aterms_prodT : ('a -> 'a -> 'a) -> (typ -> 'b -> 'a * 'b) -> typ -> 'b -> 'a * 'b
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  val map_filter_prod : (term -> term option) -> term -> term option
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  val replace_ho_args : mode -> term list -> term list -> term list
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  val ho_arg_modes_of : mode -> mode list
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  val ho_argsT_of : mode -> typ list -> typ list
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  val ho_args_of : mode -> term list -> term list
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  val ho_args_of_typ : typ -> term list -> term list
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  val ho_argsT_of_typ : typ list -> typ list
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  val split_map_mode : (mode -> term -> term option * term option)
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    -> mode -> term list -> term list * term list
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  val split_map_modeT : (mode -> typ -> typ option * typ option)
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    -> mode -> typ list -> typ list * typ list
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  val split_mode : mode -> term list -> term list * term list
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  val split_modeT' : mode -> typ list -> typ list * typ list
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  val string_of_mode : mode -> string
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  val ascii_string_of_mode : mode -> string
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  (* premises *)
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  datatype indprem = Prem of term | Negprem of term | Sidecond of term
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    | Generator of (string * typ)
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  val dest_indprem : indprem -> term
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  val map_indprem : (term -> term) -> indprem -> indprem
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  (* general syntactic functions *)
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  val conjuncts : term -> term list
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  val is_equationlike : thm -> bool
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  val is_pred_equation : thm -> bool
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  val is_intro : string -> thm -> bool
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  val is_predT : typ -> bool
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  val is_constrt : theory -> term -> bool
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  val is_constr : Proof.context -> string -> bool
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  val focus_ex : term -> Name.context -> ((string * typ) list * term) * Name.context
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  val strip_all : term -> (string * typ) list * term
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  (* introduction rule combinators *)
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  val map_atoms : (term -> term) -> term -> term
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  val fold_atoms : (term -> 'a -> 'a) -> term -> 'a -> 'a
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  val fold_map_atoms : (term -> 'a -> term * 'a) -> term -> 'a -> term * 'a
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  val maps_premises : (term -> term list) -> term -> term
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  val map_concl : (term -> term) -> term -> term
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  val map_term : theory -> (term -> term) -> thm -> thm
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  (* split theorems of case expressions *)
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  val prepare_split_thm : Proof.context -> thm -> thm
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  val find_split_thm : theory -> term -> thm option
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  (* datastructures and setup for generic compilation *)
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  datatype compilation_funs = CompilationFuns of {
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    mk_predT : typ -> typ,
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    dest_predT : typ -> typ,
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    mk_bot : typ -> term,
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    mk_single : term -> term,
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    mk_bind : term * term -> term,
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    mk_sup : term * term -> term,
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    mk_if : term -> term,
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    mk_iterate_upto : typ -> term * term * term -> term,
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    mk_not : term -> term,
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    mk_map : typ -> typ -> term -> term -> term
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  };
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  val mk_predT : compilation_funs -> typ -> typ
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  val dest_predT : compilation_funs -> typ -> typ
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  val mk_bot : compilation_funs -> typ -> term
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  val mk_single : compilation_funs -> term -> term
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  val mk_bind : compilation_funs -> term * term -> term
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  val mk_sup : compilation_funs -> term * term -> term
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  val mk_if : compilation_funs -> term -> term
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  val mk_iterate_upto : compilation_funs -> typ -> term * term * term -> term
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  val mk_not : compilation_funs -> term -> term
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  val mk_map : compilation_funs -> typ -> typ -> term -> term -> term
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  val funT_of : compilation_funs -> mode -> typ -> typ
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  (* Different compilations *)
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  datatype compilation = Pred | Depth_Limited | Random | Depth_Limited_Random | DSeq | Annotated
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    | Pos_Random_DSeq | Neg_Random_DSeq | New_Pos_Random_DSeq | New_Neg_Random_DSeq
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    | Pos_Generator_DSeq | Neg_Generator_DSeq
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  val negative_compilation_of : compilation -> compilation
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  val compilation_for_polarity : bool -> compilation -> compilation
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  val is_depth_limited_compilation : compilation -> bool 
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  val string_of_compilation : compilation -> string
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  val compilation_names : (string * compilation) list
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  val non_random_compilations : compilation list
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  val random_compilations : compilation list
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  (* Different options for compiler *)
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  datatype options = Options of {  
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    expected_modes : (string * mode list) option,
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    proposed_modes : (string * mode list) list,
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    proposed_names : ((string * mode) * string) list,
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    show_steps : bool,
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    show_proof_trace : bool,
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    show_intermediate_results : bool,
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    show_mode_inference : bool,
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    show_modes : bool,
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    show_compilation : bool,
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    show_caught_failures : bool,
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    show_invalid_clauses : bool,
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    skip_proof : bool,
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    no_topmost_reordering : bool,
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    function_flattening : bool,
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    fail_safe_function_flattening : bool,
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    specialise : bool,
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    no_higher_order_predicate : string list,
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    inductify : bool,
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    detect_switches : bool,
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    smart_depth_limiting : bool,
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    compilation : compilation
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  };
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  val expected_modes : options -> (string * mode list) option
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  val proposed_modes : options -> string -> mode list option
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  val proposed_names : options -> string -> mode -> string option
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  val show_steps : options -> bool
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  val show_proof_trace : options -> bool
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  val show_intermediate_results : options -> bool
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  val show_mode_inference : options -> bool
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  val show_modes : options -> bool
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  val show_compilation : options -> bool
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  val show_caught_failures : options -> bool
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  val show_invalid_clauses : options -> bool
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  val skip_proof : options -> bool
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  val no_topmost_reordering : options -> bool
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  val function_flattening : options -> bool
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  val fail_safe_function_flattening : options -> bool
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  val specialise : options -> bool
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  val no_higher_order_predicate : options -> string list
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  val is_inductify : options -> bool
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  val detect_switches : options -> bool
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  val smart_depth_limiting : options -> bool
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  val compilation : options -> compilation
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  val default_options : options
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  val bool_options : string list
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  val print_step : options -> string -> unit
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  (* conversions *)
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  val imp_prems_conv : conv -> conv
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  (* simple transformations *)
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  val split_conjuncts_in_assms : Proof.context -> thm -> thm
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  val dest_conjunct_prem : thm -> thm list
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  val expand_tuples : theory -> thm -> thm
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  val case_betapply : theory -> term -> term
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  val eta_contract_ho_arguments : theory -> thm -> thm
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  val remove_equalities : theory -> thm -> thm
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  val remove_pointless_clauses : thm -> thm list
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  val peephole_optimisation : theory -> thm -> thm option
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  val define_quickcheck_predicate :
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    term -> theory -> (((string * typ) * (string * typ) list) * thm) * theory
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end;
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structure Predicate_Compile_Aux : PREDICATE_COMPILE_AUX =
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struct
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(* general functions *)
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fun apfst3 f (x, y, z) = (f x, y, z)
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fun apsnd3 f (x, y, z) = (x, f y, z)
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fun aptrd3 f (x, y, z) = (x, y, f z)
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fun comb_option f (SOME x1, SOME x2) = SOME (f (x1, x2))
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  | comb_option f (NONE, SOME x2) = SOME x2
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  | comb_option f (SOME x1, NONE) = SOME x1
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  | comb_option f (NONE, NONE) = NONE
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fun map2_optional f (x :: xs) (y :: ys) = f x (SOME y) :: (map2_optional f xs ys)
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  | map2_optional f (x :: xs) [] = (f x NONE) :: (map2_optional f xs [])
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  | map2_optional f [] [] = []
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fun find_indices f xs =
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  map_filter (fn (i, true) => SOME i | (i, false) => NONE) (map_index (apsnd f) xs)
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fun assert check = if check then () else raise Fail "Assertion failed!"
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(* mode *)
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datatype mode = Bool | Input | Output | Pair of mode * mode | Fun of mode * mode
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(* equality of instantiatedness with respect to equivalences:
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  Pair Input Input == Input and Pair Output Output == Output *)
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fun eq_mode (Fun (m1, m2), Fun (m3, m4)) = eq_mode (m1, m3) andalso eq_mode (m2, m4)
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  | eq_mode (Pair (m1, m2), Pair (m3, m4)) = eq_mode (m1, m3) andalso eq_mode (m2, m4)
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  | eq_mode (Pair (m1, m2), Input) = eq_mode (m1, Input) andalso eq_mode (m2, Input)
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  | eq_mode (Pair (m1, m2), Output) = eq_mode (m1, Output) andalso eq_mode (m2, Output)
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  | eq_mode (Input, Pair (m1, m2)) = eq_mode (Input, m1) andalso eq_mode (Input, m2)
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  | eq_mode (Output, Pair (m1, m2)) = eq_mode (Output, m1) andalso eq_mode (Output, m2)
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  | eq_mode (Input, Input) = true
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  | eq_mode (Output, Output) = true
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  | eq_mode (Bool, Bool) = true
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  | eq_mode _ = false
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fun mode_ord (Input, Output) = LESS
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  | mode_ord (Output, Input) = GREATER
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  | mode_ord (Input, Input) = EQUAL
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  | mode_ord (Output, Output) = EQUAL
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  | mode_ord (Bool, Bool) = EQUAL
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  | mode_ord (Pair (m1, m2), Pair (m3, m4)) = prod_ord mode_ord mode_ord ((m1, m2), (m3, m4))
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  | mode_ord (Fun (m1, m2), Fun (m3, m4)) = prod_ord mode_ord mode_ord ((m1, m2), (m3, m4))
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fun list_fun_mode [] = Bool
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  | list_fun_mode (m :: ms) = Fun (m, list_fun_mode ms)
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(* name: binder_modes? *)
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fun strip_fun_mode (Fun (mode, mode')) = mode :: strip_fun_mode mode'
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  | strip_fun_mode Bool = []
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  | strip_fun_mode _ = raise Fail "Bad mode for strip_fun_mode"
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(* name: strip_fun_mode? *)
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fun dest_fun_mode (Fun (mode, mode')) = mode :: dest_fun_mode mode'
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  | dest_fun_mode mode = [mode]
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fun dest_tuple_mode (Pair (mode, mode')) = mode :: dest_tuple_mode mode'
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  | dest_tuple_mode _ = []
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fun all_modes_of_typ' (T as Type ("fun", _)) = 
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  let
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    val (S, U) = strip_type T
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  in
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    if U = HOLogic.boolT then
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      fold_rev (fn m1 => fn m2 => map_product (curry Fun) m1 m2)
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        (map all_modes_of_typ' S) [Bool]
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    else
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      [Input, Output]
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  end
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  | all_modes_of_typ' (Type (@{type_name Product_Type.prod}, [T1, T2])) = 
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    map_product (curry Pair) (all_modes_of_typ' T1) (all_modes_of_typ' T2)
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  | all_modes_of_typ' _ = [Input, Output]
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fun all_modes_of_typ (T as Type ("fun", _)) =
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    let
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      val (S, U) = strip_type T
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    in
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      if U = @{typ bool} then
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        fold_rev (fn m1 => fn m2 => map_product (curry Fun) m1 m2)
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          (map all_modes_of_typ' S) [Bool]
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      else
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        raise Fail "Invocation of all_modes_of_typ with a non-predicate type"
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    end
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  | all_modes_of_typ @{typ bool} = [Bool]
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  | all_modes_of_typ T =
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    raise Fail "Invocation of all_modes_of_typ with a non-predicate type"
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fun all_smodes_of_typ (T as Type ("fun", _)) =
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  let
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    val (S, U) = strip_type T
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    fun all_smodes (Type (@{type_name Product_Type.prod}, [T1, T2])) = 
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      map_product (curry Pair) (all_smodes T1) (all_smodes T2)
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      | all_smodes _ = [Input, Output]
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  in
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    if U = HOLogic.boolT then
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      fold_rev (fn m1 => fn m2 => map_product (curry Fun) m1 m2) (map all_smodes S) [Bool]
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    else
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      raise Fail "invalid type for predicate"
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  end
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fun ho_arg_modes_of mode =
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  let
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    fun ho_arg_mode (m as Fun _) =  [m]
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      | ho_arg_mode (Pair (m1, m2)) = ho_arg_mode m1 @ ho_arg_mode m2
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      | ho_arg_mode _ = []
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  in
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    maps ho_arg_mode (strip_fun_mode mode)
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  end
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fun ho_args_of mode ts =
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  let
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    fun ho_arg (Fun _) (SOME t) = [t]
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      | ho_arg (Fun _) NONE = raise Fail "mode and term do not match"
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      | ho_arg (Pair (m1, m2)) (SOME (Const (@{const_name Pair}, _) $ t1 $ t2)) =
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          ho_arg m1 (SOME t1) @ ho_arg m2 (SOME t2)
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      | ho_arg (Pair (m1, m2)) NONE = ho_arg m1 NONE @ ho_arg m2 NONE
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      | ho_arg _ _ = []
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  in
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    flat (map2_optional ho_arg (strip_fun_mode mode) ts)
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  end
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fun ho_args_of_typ T ts =
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  let
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    fun ho_arg (T as Type("fun", [_,_])) (SOME t) = if body_type T = @{typ bool} then [t] else []
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      | ho_arg (Type("fun", [_,_])) NONE = raise Fail "mode and term do not match"
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      | ho_arg (Type(@{type_name "Product_Type.prod"}, [T1, T2]))
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         (SOME (Const (@{const_name Pair}, _) $ t1 $ t2)) =
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          ho_arg T1 (SOME t1) @ ho_arg T2 (SOME t2)
bulwahn@39299
   296
      | ho_arg (Type(@{type_name "Product_Type.prod"}, [T1, T2])) NONE =
bulwahn@39299
   297
          ho_arg T1 NONE @ ho_arg T2 NONE
bulwahn@39299
   298
      | ho_arg _ _ = []
bulwahn@39299
   299
  in
bulwahn@39299
   300
    flat (map2_optional ho_arg (binder_types T) ts)
bulwahn@39299
   301
  end
bulwahn@39299
   302
bulwahn@39299
   303
fun ho_argsT_of_typ Ts =
bulwahn@39299
   304
  let
bulwahn@39312
   305
    fun ho_arg (T as Type("fun", [_,_])) = if body_type T = @{typ bool} then [T] else []
bulwahn@39299
   306
      | ho_arg (Type(@{type_name "Product_Type.prod"}, [T1, T2])) =
bulwahn@39299
   307
          ho_arg T1 @ ho_arg T2
bulwahn@39299
   308
      | ho_arg _ = []
bulwahn@39299
   309
  in
bulwahn@39299
   310
    maps ho_arg Ts
bulwahn@39299
   311
  end
bulwahn@39299
   312
  
bulwahn@39299
   313
bulwahn@34948
   314
(* temporary function should be replaced by unsplit_input or so? *)
bulwahn@34948
   315
fun replace_ho_args mode hoargs ts =
bulwahn@34948
   316
  let
bulwahn@34948
   317
    fun replace (Fun _, _) (arg' :: hoargs') = (arg', hoargs')
haftmann@37391
   318
      | replace (Pair (m1, m2), Const (@{const_name Pair}, T) $ t1 $ t2) hoargs =
bulwahn@34948
   319
        let
bulwahn@34948
   320
          val (t1', hoargs') = replace (m1, t1) hoargs
bulwahn@34948
   321
          val (t2', hoargs'') = replace (m2, t2) hoargs'
bulwahn@34948
   322
        in
haftmann@37391
   323
          (Const (@{const_name Pair}, T) $ t1' $ t2', hoargs'')
bulwahn@34948
   324
        end
bulwahn@34948
   325
      | replace (_, t) hoargs = (t, hoargs)
bulwahn@34948
   326
  in
bulwahn@35885
   327
    fst (fold_map replace (strip_fun_mode mode ~~ ts) hoargs)
bulwahn@34948
   328
  end
bulwahn@34948
   329
bulwahn@34948
   330
fun ho_argsT_of mode Ts =
bulwahn@34948
   331
  let
bulwahn@34948
   332
    fun ho_arg (Fun _) T = [T]
haftmann@37678
   333
      | ho_arg (Pair (m1, m2)) (Type (@{type_name Product_Type.prod}, [T1, T2])) = ho_arg m1 T1 @ ho_arg m2 T2
bulwahn@34948
   334
      | ho_arg _ _ = []
bulwahn@34948
   335
  in
bulwahn@34948
   336
    flat (map2 ho_arg (strip_fun_mode mode) Ts)
bulwahn@34948
   337
  end
bulwahn@34948
   338
bulwahn@34948
   339
(* splits mode and maps function to higher-order argument types *)
bulwahn@34948
   340
fun split_map_mode f mode ts =
bulwahn@34948
   341
  let
bulwahn@34948
   342
    fun split_arg_mode' (m as Fun _) t = f m t
haftmann@37391
   343
      | split_arg_mode' (Pair (m1, m2)) (Const (@{const_name Pair}, _) $ t1 $ t2) =
bulwahn@34948
   344
        let
bulwahn@34948
   345
          val (i1, o1) = split_arg_mode' m1 t1
bulwahn@34948
   346
          val (i2, o2) = split_arg_mode' m2 t2
bulwahn@34948
   347
        in
bulwahn@34948
   348
          (comb_option HOLogic.mk_prod (i1, i2), comb_option HOLogic.mk_prod (o1, o2))
bulwahn@34948
   349
        end
bulwahn@35324
   350
      | split_arg_mode' m t =
bulwahn@35324
   351
        if eq_mode (m, Input) then (SOME t, NONE)
bulwahn@35324
   352
        else if eq_mode (m, Output) then (NONE,  SOME t)
bulwahn@35885
   353
        else raise Fail "split_map_mode: mode and term do not match"
bulwahn@34948
   354
  in
bulwahn@34948
   355
    (pairself (map_filter I) o split_list) (map2 split_arg_mode' (strip_fun_mode mode) ts)
bulwahn@34948
   356
  end
bulwahn@34948
   357
bulwahn@34948
   358
(* splits mode and maps function to higher-order argument types *)
bulwahn@34948
   359
fun split_map_modeT f mode Ts =
bulwahn@34948
   360
  let
bulwahn@34948
   361
    fun split_arg_mode' (m as Fun _) T = f m T
haftmann@37678
   362
      | split_arg_mode' (Pair (m1, m2)) (Type (@{type_name Product_Type.prod}, [T1, T2])) =
bulwahn@34948
   363
        let
bulwahn@34948
   364
          val (i1, o1) = split_arg_mode' m1 T1
bulwahn@34948
   365
          val (i2, o2) = split_arg_mode' m2 T2
bulwahn@34948
   366
        in
bulwahn@34948
   367
          (comb_option HOLogic.mk_prodT (i1, i2), comb_option HOLogic.mk_prodT (o1, o2))
bulwahn@34948
   368
        end
bulwahn@34948
   369
      | split_arg_mode' Input T = (SOME T, NONE)
bulwahn@34948
   370
      | split_arg_mode' Output T = (NONE,  SOME T)
bulwahn@35885
   371
      | split_arg_mode' _ _ = raise Fail "split_modeT': mode and type do not match"
bulwahn@34948
   372
  in
bulwahn@34948
   373
    (pairself (map_filter I) o split_list) (map2 split_arg_mode' (strip_fun_mode mode) Ts)
bulwahn@34948
   374
  end
bulwahn@34948
   375
bulwahn@34948
   376
fun split_mode mode ts = split_map_mode (fn _ => fn _ => (NONE, NONE)) mode ts
bulwahn@34948
   377
haftmann@37678
   378
fun fold_map_aterms_prodT comb f (Type (@{type_name Product_Type.prod}, [T1, T2])) s =
bulwahn@34948
   379
  let
bulwahn@34948
   380
    val (x1, s') = fold_map_aterms_prodT comb f T1 s
bulwahn@34948
   381
    val (x2, s'') = fold_map_aterms_prodT comb f T2 s'
bulwahn@34948
   382
  in
bulwahn@34948
   383
    (comb x1 x2, s'')
bulwahn@34948
   384
  end
bulwahn@34948
   385
  | fold_map_aterms_prodT comb f T s = f T s
bulwahn@34948
   386
haftmann@37391
   387
fun map_filter_prod f (Const (@{const_name Pair}, _) $ t1 $ t2) =
bulwahn@34948
   388
  comb_option HOLogic.mk_prod (map_filter_prod f t1, map_filter_prod f t2)
bulwahn@34948
   389
  | map_filter_prod f t = f t
bulwahn@34948
   390
bulwahn@34948
   391
(* obviously, split_mode' and split_modeT' do not match? where does that cause problems? *)
bulwahn@34948
   392
  
bulwahn@34948
   393
fun split_modeT' mode Ts =
bulwahn@34948
   394
  let
bulwahn@34948
   395
    fun split_arg_mode' (Fun _) T = ([], [])
haftmann@37678
   396
      | split_arg_mode' (Pair (m1, m2)) (Type (@{type_name Product_Type.prod}, [T1, T2])) =
bulwahn@34948
   397
        let
bulwahn@34948
   398
          val (i1, o1) = split_arg_mode' m1 T1
bulwahn@34948
   399
          val (i2, o2) = split_arg_mode' m2 T2
bulwahn@34948
   400
        in
bulwahn@34948
   401
          (i1 @ i2, o1 @ o2)
bulwahn@34948
   402
        end
bulwahn@34948
   403
      | split_arg_mode' Input T = ([T], [])
bulwahn@34948
   404
      | split_arg_mode' Output T = ([], [T])
bulwahn@35885
   405
      | split_arg_mode' _ _ = raise Fail "split_modeT': mode and type do not match"
bulwahn@34948
   406
  in
bulwahn@34948
   407
    (pairself flat o split_list) (map2 split_arg_mode' (strip_fun_mode mode) Ts)
bulwahn@34948
   408
  end
bulwahn@34948
   409
bulwahn@34948
   410
fun string_of_mode mode =
bulwahn@33619
   411
  let
bulwahn@33619
   412
    fun string_of_mode1 Input = "i"
bulwahn@33619
   413
      | string_of_mode1 Output = "o"
bulwahn@33619
   414
      | string_of_mode1 Bool = "bool"
bulwahn@33619
   415
      | string_of_mode1 mode = "(" ^ (string_of_mode3 mode) ^ ")"
bulwahn@33626
   416
    and string_of_mode2 (Pair (m1, m2)) = string_of_mode3 m1 ^ " * " ^  string_of_mode2 m2
bulwahn@33619
   417
      | string_of_mode2 mode = string_of_mode1 mode
bulwahn@33619
   418
    and string_of_mode3 (Fun (m1, m2)) = string_of_mode2 m1 ^ " => " ^ string_of_mode3 m2
bulwahn@33619
   419
      | string_of_mode3 mode = string_of_mode2 mode
bulwahn@34948
   420
  in string_of_mode3 mode end
bulwahn@33619
   421
bulwahn@34948
   422
fun ascii_string_of_mode mode' =
bulwahn@33626
   423
  let
bulwahn@33626
   424
    fun ascii_string_of_mode' Input = "i"
bulwahn@33626
   425
      | ascii_string_of_mode' Output = "o"
bulwahn@33626
   426
      | ascii_string_of_mode' Bool = "b"
bulwahn@33626
   427
      | ascii_string_of_mode' (Pair (m1, m2)) =
bulwahn@33626
   428
          "P" ^ ascii_string_of_mode' m1 ^ ascii_string_of_mode'_Pair m2
bulwahn@33626
   429
      | ascii_string_of_mode' (Fun (m1, m2)) = 
bulwahn@33626
   430
          "F" ^ ascii_string_of_mode' m1 ^ ascii_string_of_mode'_Fun m2 ^ "B"
bulwahn@33626
   431
    and ascii_string_of_mode'_Fun (Fun (m1, m2)) =
bulwahn@33626
   432
          ascii_string_of_mode' m1 ^ (if m2 = Bool then "" else "_" ^ ascii_string_of_mode'_Fun m2)
bulwahn@33626
   433
      | ascii_string_of_mode'_Fun Bool = "B"
bulwahn@33626
   434
      | ascii_string_of_mode'_Fun m = ascii_string_of_mode' m
bulwahn@33626
   435
    and ascii_string_of_mode'_Pair (Pair (m1, m2)) =
bulwahn@33626
   436
          ascii_string_of_mode' m1 ^ ascii_string_of_mode'_Pair m2
bulwahn@33626
   437
      | ascii_string_of_mode'_Pair m = ascii_string_of_mode' m
bulwahn@33626
   438
  in ascii_string_of_mode'_Fun mode' end
bulwahn@33626
   439
bulwahn@34948
   440
(* premises *)
bulwahn@33619
   441
bulwahn@34948
   442
datatype indprem = Prem of term | Negprem of term | Sidecond of term
bulwahn@34948
   443
  | Generator of (string * typ);
bulwahn@33619
   444
bulwahn@36251
   445
fun dest_indprem (Prem t) = t
bulwahn@36251
   446
  | dest_indprem (Negprem t) = t
bulwahn@36251
   447
  | dest_indprem (Sidecond t) = t
bulwahn@36251
   448
  | dest_indprem (Generator _) = raise Fail "cannot destruct generator"
bulwahn@36251
   449
bulwahn@36254
   450
fun map_indprem f (Prem t) = Prem (f t)
bulwahn@36254
   451
  | map_indprem f (Negprem t) = Negprem (f t)
bulwahn@36254
   452
  | map_indprem f (Sidecond t) = Sidecond (f t)
bulwahn@36254
   453
  | map_indprem f (Generator (v, T)) = Generator (dest_Free (f (Free (v, T))))
bulwahn@36254
   454
bulwahn@33250
   455
(* general syntactic functions *)
bulwahn@33250
   456
bulwahn@33250
   457
(*Like dest_conj, but flattens conjunctions however nested*)
haftmann@38795
   458
fun conjuncts_aux (Const (@{const_name HOL.conj}, _) $ t $ t') conjs = conjuncts_aux t (conjuncts_aux t' conjs)
bulwahn@33250
   459
  | conjuncts_aux t conjs = t::conjs;
bulwahn@33250
   460
bulwahn@33250
   461
fun conjuncts t = conjuncts_aux t [];
bulwahn@33250
   462
bulwahn@33250
   463
fun is_equationlike_term (Const ("==", _) $ _ $ _) = true
haftmann@38864
   464
  | is_equationlike_term (Const (@{const_name Trueprop}, _) $ (Const (@{const_name HOL.eq}, _) $ _ $ _)) = true
bulwahn@33250
   465
  | is_equationlike_term _ = false
bulwahn@33250
   466
  
bulwahn@33250
   467
val is_equationlike = is_equationlike_term o prop_of 
bulwahn@33250
   468
bulwahn@33250
   469
fun is_pred_equation_term (Const ("==", _) $ u $ v) =
bulwahn@33250
   470
  (fastype_of u = @{typ bool}) andalso (fastype_of v = @{typ bool})
bulwahn@33250
   471
  | is_pred_equation_term _ = false
bulwahn@33250
   472
  
bulwahn@33250
   473
val is_pred_equation = is_pred_equation_term o prop_of 
bulwahn@33250
   474
bulwahn@33250
   475
fun is_intro_term constname t =
bulwahn@34948
   476
  the_default false (try (fn t => case fst (strip_comb (HOLogic.dest_Trueprop (Logic.strip_imp_concl t))) of
bulwahn@33250
   477
    Const (c, _) => c = constname
bulwahn@34948
   478
  | _ => false) t)
bulwahn@33250
   479
  
bulwahn@33250
   480
fun is_intro constname t = is_intro_term constname (prop_of t)
bulwahn@33250
   481
haftmann@38552
   482
fun is_pred thy constname = (body_type (Sign.the_const_type thy constname) = HOLogic.boolT);
bulwahn@33250
   483
bulwahn@35885
   484
fun is_predT (T as Type("fun", [_, _])) = (snd (strip_type T) = @{typ bool})
bulwahn@33250
   485
  | is_predT _ = false
bulwahn@33250
   486
bulwahn@33250
   487
(*** check if a term contains only constructor functions ***)
bulwahn@34948
   488
(* TODO: another copy in the core! *)
bulwahn@33623
   489
(* FIXME: constructor terms are supposed to be seen in the way the code generator
bulwahn@33623
   490
  sees constructors.*)
bulwahn@33250
   491
fun is_constrt thy =
bulwahn@33250
   492
  let
bulwahn@33250
   493
    val cnstrs = flat (maps
bulwahn@33250
   494
      (map (fn (_, (Tname, _, cs)) => map (apsnd (rpair Tname o length)) cs) o #descr o snd)
bulwahn@33250
   495
      (Symtab.dest (Datatype.get_all thy)));
bulwahn@33250
   496
    fun check t = (case strip_comb t of
bulwahn@36032
   497
        (Var _, []) => true
bulwahn@36032
   498
      | (Free _, []) => true
bulwahn@33250
   499
      | (Const (s, T), ts) => (case (AList.lookup (op =) cnstrs s, body_type T) of
bulwahn@33250
   500
            (SOME (i, Tname), Type (Tname', _)) => length ts = i andalso Tname = Tname' andalso forall check ts
bulwahn@33250
   501
          | _ => false)
bulwahn@33250
   502
      | _ => false)
bulwahn@36032
   503
  in check end;
bulwahn@34948
   504
bulwahn@34948
   505
fun is_funtype (Type ("fun", [_, _])) = true
bulwahn@34948
   506
  | is_funtype _ = false;
bulwahn@34948
   507
bulwahn@34948
   508
fun is_Type (Type _) = true
bulwahn@34948
   509
  | is_Type _ = false
bulwahn@34948
   510
bulwahn@34948
   511
(* returns true if t is an application of an datatype constructor *)
bulwahn@34948
   512
(* which then consequently would be splitted *)
bulwahn@34948
   513
(* else false *)
bulwahn@34948
   514
(*
bulwahn@34948
   515
fun is_constructor thy t =
bulwahn@34948
   516
  if (is_Type (fastype_of t)) then
bulwahn@34948
   517
    (case DatatypePackage.get_datatype thy ((fst o dest_Type o fastype_of) t) of
bulwahn@34948
   518
      NONE => false
bulwahn@34948
   519
    | SOME info => (let
bulwahn@34948
   520
      val constr_consts = maps (fn (_, (_, _, constrs)) => map fst constrs) (#descr info)
bulwahn@34948
   521
      val (c, _) = strip_comb t
bulwahn@34948
   522
      in (case c of
bulwahn@34948
   523
        Const (name, _) => name mem_string constr_consts
bulwahn@34948
   524
        | _ => false) end))
bulwahn@34948
   525
  else false
bulwahn@34948
   526
*)
bulwahn@34948
   527
bulwahn@35891
   528
val is_constr = Code.is_constr o ProofContext.theory_of;
bulwahn@34948
   529
bulwahn@36047
   530
fun strip_all t = (Term.strip_all_vars t, Term.strip_all_body t)
bulwahn@36047
   531
haftmann@38558
   532
fun strip_ex (Const (@{const_name Ex}, _) $ Abs (x, T, t)) =
bulwahn@33250
   533
  let
bulwahn@33250
   534
    val (xTs, t') = strip_ex t
bulwahn@33250
   535
  in
bulwahn@33250
   536
    ((x, T) :: xTs, t')
bulwahn@33250
   537
  end
bulwahn@33250
   538
  | strip_ex t = ([], t)
bulwahn@33250
   539
bulwahn@33250
   540
fun focus_ex t nctxt =
bulwahn@33250
   541
  let
bulwahn@33250
   542
    val ((xs, Ts), t') = apfst split_list (strip_ex t) 
bulwahn@33250
   543
    val (xs', nctxt') = Name.variants xs nctxt;
bulwahn@33250
   544
    val ps' = xs' ~~ Ts;
bulwahn@33250
   545
    val vs = map Free ps';
bulwahn@33250
   546
    val t'' = Term.subst_bounds (rev vs, t');
bulwahn@33250
   547
  in ((ps', t''), nctxt') end;
bulwahn@33250
   548
bulwahn@33250
   549
(* introduction rule combinators *)
bulwahn@33250
   550
bulwahn@33250
   551
fun map_atoms f intro = 
bulwahn@33250
   552
  let
bulwahn@33250
   553
    val (literals, head) = Logic.strip_horn intro
bulwahn@33250
   554
    fun appl t = (case t of
bulwahn@35885
   555
        (@{term Not} $ t') => HOLogic.mk_not (f t')
bulwahn@33250
   556
      | _ => f t)
bulwahn@33250
   557
  in
bulwahn@33250
   558
    Logic.list_implies
bulwahn@33250
   559
      (map (HOLogic.mk_Trueprop o appl o HOLogic.dest_Trueprop) literals, head)
bulwahn@33250
   560
  end
bulwahn@33250
   561
bulwahn@33250
   562
fun fold_atoms f intro s =
bulwahn@33250
   563
  let
bulwahn@33250
   564
    val (literals, head) = Logic.strip_horn intro
bulwahn@33250
   565
    fun appl t s = (case t of
bulwahn@35885
   566
      (@{term Not} $ t') => f t' s
bulwahn@33250
   567
      | _ => f t s)
bulwahn@33250
   568
  in fold appl (map HOLogic.dest_Trueprop literals) s end
bulwahn@33250
   569
bulwahn@33250
   570
fun fold_map_atoms f intro s =
bulwahn@33250
   571
  let
bulwahn@33250
   572
    val (literals, head) = Logic.strip_horn intro
bulwahn@33250
   573
    fun appl t s = (case t of
bulwahn@35885
   574
      (@{term Not} $ t') => apfst HOLogic.mk_not (f t' s)
bulwahn@33250
   575
      | _ => f t s)
bulwahn@33250
   576
    val (literals', s') = fold_map appl (map HOLogic.dest_Trueprop literals) s
bulwahn@33250
   577
  in
bulwahn@33250
   578
    (Logic.list_implies (map HOLogic.mk_Trueprop literals', head), s')
bulwahn@33250
   579
  end;
bulwahn@33250
   580
bulwahn@36246
   581
fun map_premises f intro =
bulwahn@36246
   582
  let
bulwahn@36246
   583
    val (premises, head) = Logic.strip_horn intro
bulwahn@36246
   584
  in
bulwahn@36246
   585
    Logic.list_implies (map f premises, head)
bulwahn@36246
   586
  end
bulwahn@36246
   587
bulwahn@36246
   588
fun map_filter_premises f intro =
bulwahn@36246
   589
  let
bulwahn@36246
   590
    val (premises, head) = Logic.strip_horn intro
bulwahn@36246
   591
  in
bulwahn@36246
   592
    Logic.list_implies (map_filter f premises, head)
bulwahn@36246
   593
  end
bulwahn@36246
   594
bulwahn@33250
   595
fun maps_premises f intro =
bulwahn@33250
   596
  let
bulwahn@33250
   597
    val (premises, head) = Logic.strip_horn intro
bulwahn@33250
   598
  in
bulwahn@33250
   599
    Logic.list_implies (maps f premises, head)
bulwahn@33250
   600
  end
bulwahn@35324
   601
bulwahn@35875
   602
fun map_concl f intro =
bulwahn@35875
   603
  let
bulwahn@35875
   604
    val (premises, head) = Logic.strip_horn intro
bulwahn@35875
   605
  in
bulwahn@35875
   606
    Logic.list_implies (premises, f head)
bulwahn@35875
   607
  end
bulwahn@35875
   608
bulwahn@35875
   609
(* combinators to apply a function to all basic parts of nested products *)
bulwahn@35875
   610
haftmann@37391
   611
fun map_products f (Const (@{const_name Pair}, T) $ t1 $ t2) =
haftmann@37391
   612
  Const (@{const_name Pair}, T) $ map_products f t1 $ map_products f t2
bulwahn@35875
   613
  | map_products f t = f t
bulwahn@35324
   614
bulwahn@35324
   615
(* split theorems of case expressions *)
bulwahn@35324
   616
bulwahn@35324
   617
fun prepare_split_thm ctxt split_thm =
bulwahn@35324
   618
    (split_thm RS @{thm iffD2})
wenzelm@35624
   619
    |> Local_Defs.unfold ctxt [@{thm atomize_conjL[symmetric]},
bulwahn@35324
   620
      @{thm atomize_all[symmetric]}, @{thm atomize_imp[symmetric]}]
bulwahn@35324
   621
bulwahn@36029
   622
fun find_split_thm thy (Const (name, T)) = Option.map #split (Datatype_Data.info_of_case thy name)
bulwahn@36029
   623
  | find_split_thm thy _ = NONE
bulwahn@35324
   624
bulwahn@33250
   625
(* lifting term operations to theorems *)
bulwahn@33250
   626
bulwahn@33250
   627
fun map_term thy f th =
bulwahn@33250
   628
  Skip_Proof.make_thm thy (f (prop_of th))
bulwahn@33250
   629
bulwahn@33250
   630
(*
bulwahn@33250
   631
fun equals_conv lhs_cv rhs_cv ct =
bulwahn@33250
   632
  case Thm.term_of ct of
bulwahn@33250
   633
    Const ("==", _) $ _ $ _ => Conv.arg_conv cv ct  
bulwahn@33250
   634
  | _ => error "equals_conv"  
bulwahn@33250
   635
*)
bulwahn@33250
   636
bulwahn@36038
   637
(* Different compilations *)
bulwahn@33250
   638
bulwahn@35881
   639
datatype compilation = Pred | Depth_Limited | Random | Depth_Limited_Random | DSeq | Annotated
bulwahn@40051
   640
  | Pos_Random_DSeq | Neg_Random_DSeq | New_Pos_Random_DSeq | New_Neg_Random_DSeq |
bulwahn@40051
   641
    Pos_Generator_DSeq | Neg_Generator_DSeq
bulwahn@35324
   642
bulwahn@35324
   643
fun negative_compilation_of Pos_Random_DSeq = Neg_Random_DSeq
bulwahn@35324
   644
  | negative_compilation_of Neg_Random_DSeq = Pos_Random_DSeq
bulwahn@36018
   645
  | negative_compilation_of New_Pos_Random_DSeq = New_Neg_Random_DSeq
bulwahn@36018
   646
  | negative_compilation_of New_Neg_Random_DSeq = New_Pos_Random_DSeq
bulwahn@40051
   647
  | negative_compilation_of Pos_Generator_DSeq = Neg_Generator_DSeq
bulwahn@40051
   648
  | negative_compilation_of Pos_Generator_DSeq = Pos_Generator_DSeq
bulwahn@35324
   649
  | negative_compilation_of c = c
bulwahn@35324
   650
  
bulwahn@35324
   651
fun compilation_for_polarity false Pos_Random_DSeq = Neg_Random_DSeq
bulwahn@36018
   652
  | compilation_for_polarity false New_Pos_Random_DSeq = New_Neg_Random_DSeq
bulwahn@35324
   653
  | compilation_for_polarity _ c = c
bulwahn@34948
   654
bulwahn@40049
   655
fun is_depth_limited_compilation c =
bulwahn@40051
   656
  (c = New_Pos_Random_DSeq) orelse (c = New_Neg_Random_DSeq) orelse
bulwahn@40051
   657
  (c = Pos_Generator_DSeq) orelse (c = Pos_Generator_DSeq)
bulwahn@40049
   658
bulwahn@35885
   659
fun string_of_compilation c =
bulwahn@35885
   660
  case c of
bulwahn@34948
   661
    Pred => ""
bulwahn@34948
   662
  | Random => "random"
bulwahn@34948
   663
  | Depth_Limited => "depth limited"
bulwahn@35881
   664
  | Depth_Limited_Random => "depth limited random"
bulwahn@34948
   665
  | DSeq => "dseq"
bulwahn@34948
   666
  | Annotated => "annotated"
bulwahn@35324
   667
  | Pos_Random_DSeq => "pos_random dseq"
bulwahn@35324
   668
  | Neg_Random_DSeq => "neg_random_dseq"
bulwahn@36018
   669
  | New_Pos_Random_DSeq => "new_pos_random dseq"
bulwahn@36018
   670
  | New_Neg_Random_DSeq => "new_neg_random_dseq"
bulwahn@40051
   671
  | Pos_Generator_DSeq => "pos_generator_dseq"
bulwahn@40051
   672
  | Neg_Generator_DSeq => "neg_generator_dseq"
bulwahn@36038
   673
bulwahn@36018
   674
val compilation_names = [("pred", Pred),
bulwahn@36018
   675
  ("random", Random),
bulwahn@36018
   676
  ("depth_limited", Depth_Limited),
bulwahn@36018
   677
  ("depth_limited_random", Depth_Limited_Random),
bulwahn@36018
   678
  (*("annotated", Annotated),*)
bulwahn@40054
   679
  ("dseq", DSeq),
bulwahn@40054
   680
  ("random_dseq", Pos_Random_DSeq),
bulwahn@40051
   681
  ("new_random_dseq", New_Pos_Random_DSeq),
bulwahn@40051
   682
  ("generator_dseq", Pos_Generator_DSeq)]
bulwahn@36038
   683
bulwahn@36038
   684
val non_random_compilations = [Pred, Depth_Limited, DSeq, Annotated]
bulwahn@36038
   685
bulwahn@36038
   686
bulwahn@36038
   687
val random_compilations = [Random, Depth_Limited_Random,
bulwahn@36038
   688
  Pos_Random_DSeq, Neg_Random_DSeq, New_Pos_Random_DSeq, New_Neg_Random_DSeq]
bulwahn@36038
   689
bulwahn@36046
   690
(* datastructures and setup for generic compilation *)
bulwahn@36046
   691
bulwahn@36046
   692
datatype compilation_funs = CompilationFuns of {
bulwahn@36046
   693
  mk_predT : typ -> typ,
bulwahn@36046
   694
  dest_predT : typ -> typ,
bulwahn@36046
   695
  mk_bot : typ -> term,
bulwahn@36046
   696
  mk_single : term -> term,
bulwahn@36046
   697
  mk_bind : term * term -> term,
bulwahn@36046
   698
  mk_sup : term * term -> term,
bulwahn@36046
   699
  mk_if : term -> term,
bulwahn@36049
   700
  mk_iterate_upto : typ -> term * term * term -> term,
bulwahn@36046
   701
  mk_not : term -> term,
bulwahn@36046
   702
  mk_map : typ -> typ -> term -> term -> term
bulwahn@36046
   703
};
bulwahn@36038
   704
bulwahn@36046
   705
fun mk_predT (CompilationFuns funs) = #mk_predT funs
bulwahn@36046
   706
fun dest_predT (CompilationFuns funs) = #dest_predT funs
bulwahn@36046
   707
fun mk_bot (CompilationFuns funs) = #mk_bot funs
bulwahn@36046
   708
fun mk_single (CompilationFuns funs) = #mk_single funs
bulwahn@36046
   709
fun mk_bind (CompilationFuns funs) = #mk_bind funs
bulwahn@36046
   710
fun mk_sup (CompilationFuns funs) = #mk_sup funs
bulwahn@36046
   711
fun mk_if (CompilationFuns funs) = #mk_if funs
bulwahn@36049
   712
fun mk_iterate_upto (CompilationFuns funs) = #mk_iterate_upto funs
bulwahn@36046
   713
fun mk_not (CompilationFuns funs) = #mk_not funs
bulwahn@36046
   714
fun mk_map (CompilationFuns funs) = #mk_map funs
bulwahn@36046
   715
bulwahn@36046
   716
(** function types and names of different compilations **)
bulwahn@36046
   717
bulwahn@36046
   718
fun funT_of compfuns mode T =
bulwahn@36046
   719
  let
bulwahn@36046
   720
    val Ts = binder_types T
bulwahn@36046
   721
    val (inTs, outTs) = split_map_modeT (fn m => fn T => (SOME (funT_of compfuns m T), NONE)) mode Ts
bulwahn@36046
   722
  in
bulwahn@36046
   723
    inTs ---> (mk_predT compfuns (HOLogic.mk_tupleT outTs))
bulwahn@36046
   724
  end;
bulwahn@36046
   725
bulwahn@36046
   726
(* Different options for compiler *)
bulwahn@34948
   727
bulwahn@33250
   728
datatype options = Options of {  
bulwahn@34948
   729
  expected_modes : (string * mode list) option,
bulwahn@39382
   730
  proposed_modes : (string * mode list) list,
bulwahn@34948
   731
  proposed_names : ((string * mode) * string) list,
bulwahn@33250
   732
  show_steps : bool,
bulwahn@33250
   733
  show_proof_trace : bool,
bulwahn@33250
   734
  show_intermediate_results : bool,
bulwahn@33251
   735
  show_mode_inference : bool,
bulwahn@33251
   736
  show_modes : bool,
bulwahn@33250
   737
  show_compilation : bool,
bulwahn@35324
   738
  show_caught_failures : bool,
bulwahn@39383
   739
  show_invalid_clauses : bool,
bulwahn@33250
   740
  skip_proof : bool,
bulwahn@35324
   741
  no_topmost_reordering : bool,
bulwahn@35324
   742
  function_flattening : bool,
bulwahn@36248
   743
  specialise : bool,
bulwahn@35324
   744
  fail_safe_function_flattening : bool,
bulwahn@35324
   745
  no_higher_order_predicate : string list,
bulwahn@33250
   746
  inductify : bool,
bulwahn@36254
   747
  detect_switches : bool,
bulwahn@40048
   748
  smart_depth_limiting : bool,
bulwahn@34948
   749
  compilation : compilation
bulwahn@33250
   750
};
bulwahn@33250
   751
bulwahn@33250
   752
fun expected_modes (Options opt) = #expected_modes opt
bulwahn@39382
   753
fun proposed_modes (Options opt) = AList.lookup (op =) (#proposed_modes opt)
bulwahn@34948
   754
fun proposed_names (Options opt) name mode = AList.lookup (eq_pair (op =) eq_mode)
bulwahn@33623
   755
  (#proposed_names opt) (name, mode)
bulwahn@33620
   756
bulwahn@33250
   757
fun show_steps (Options opt) = #show_steps opt
bulwahn@33250
   758
fun show_intermediate_results (Options opt) = #show_intermediate_results opt
bulwahn@33250
   759
fun show_proof_trace (Options opt) = #show_proof_trace opt
bulwahn@33251
   760
fun show_modes (Options opt) = #show_modes opt
bulwahn@33251
   761
fun show_mode_inference (Options opt) = #show_mode_inference opt
bulwahn@33250
   762
fun show_compilation (Options opt) = #show_compilation opt
bulwahn@35324
   763
fun show_caught_failures (Options opt) = #show_caught_failures opt
bulwahn@39383
   764
fun show_invalid_clauses (Options opt) = #show_invalid_clauses opt
bulwahn@33250
   765
fun skip_proof (Options opt) = #skip_proof opt
bulwahn@33250
   766
bulwahn@35324
   767
fun function_flattening (Options opt) = #function_flattening opt
bulwahn@35324
   768
fun fail_safe_function_flattening (Options opt) = #fail_safe_function_flattening opt
bulwahn@36248
   769
fun specialise (Options opt) = #specialise opt
bulwahn@35324
   770
fun no_topmost_reordering (Options opt) = #no_topmost_reordering opt
bulwahn@35324
   771
fun no_higher_order_predicate (Options opt) = #no_higher_order_predicate opt
bulwahn@35324
   772
bulwahn@33250
   773
fun is_inductify (Options opt) = #inductify opt
bulwahn@34948
   774
bulwahn@34948
   775
fun compilation (Options opt) = #compilation opt
bulwahn@33250
   776
bulwahn@36254
   777
fun detect_switches (Options opt) = #detect_switches opt
bulwahn@36254
   778
bulwahn@40048
   779
fun smart_depth_limiting (Options opt) = #smart_depth_limiting opt
bulwahn@40048
   780
bulwahn@33250
   781
val default_options = Options {
bulwahn@33250
   782
  expected_modes = NONE,
bulwahn@39382
   783
  proposed_modes = [],
bulwahn@33623
   784
  proposed_names = [],
bulwahn@33250
   785
  show_steps = false,
bulwahn@33250
   786
  show_intermediate_results = false,
bulwahn@33250
   787
  show_proof_trace = false,
bulwahn@33251
   788
  show_modes = false,
bulwahn@33250
   789
  show_mode_inference = false,
bulwahn@33250
   790
  show_compilation = false,
bulwahn@35324
   791
  show_caught_failures = false,
bulwahn@39383
   792
  show_invalid_clauses = false,
bulwahn@34948
   793
  skip_proof = true,
bulwahn@35324
   794
  no_topmost_reordering = false,
bulwahn@35324
   795
  function_flattening = false,
bulwahn@36248
   796
  specialise = false,
bulwahn@35324
   797
  fail_safe_function_flattening = false,
bulwahn@35324
   798
  no_higher_order_predicate = [],
bulwahn@33250
   799
  inductify = false,
bulwahn@36254
   800
  detect_switches = true,
bulwahn@40048
   801
  smart_depth_limiting = false,
bulwahn@34948
   802
  compilation = Pred
bulwahn@33250
   803
}
bulwahn@33250
   804
bulwahn@34948
   805
val bool_options = ["show_steps", "show_intermediate_results", "show_proof_trace", "show_modes",
bulwahn@39383
   806
  "show_mode_inference", "show_compilation", "show_invalid_clauses", "skip_proof", "inductify",
bulwahn@40048
   807
  "no_function_flattening", "detect_switches", "specialise", "no_topmost_reordering",
bulwahn@40048
   808
  "smart_depth_limiting"]
bulwahn@34948
   809
bulwahn@33250
   810
fun print_step options s =
bulwahn@33250
   811
  if show_steps options then tracing s else ()
bulwahn@33250
   812
bulwahn@36047
   813
(* simple transformations *)
bulwahn@36047
   814
bulwahn@36047
   815
(** tuple processing **)
bulwahn@33250
   816
bulwahn@39657
   817
fun rewrite_args [] (pats, intro_t, ctxt) = (pats, intro_t, ctxt)
bulwahn@39657
   818
  | rewrite_args (arg::args) (pats, intro_t, ctxt) = 
bulwahn@39657
   819
    (case HOLogic.strip_tupleT (fastype_of arg) of
bulwahn@39657
   820
      (Ts as _ :: _ :: _) =>
bulwahn@39657
   821
      let
bulwahn@39657
   822
        fun rewrite_arg' (Const (@{const_name Pair}, _) $ _ $ t2, Type (@{type_name Product_Type.prod}, [_, T2]))
bulwahn@39657
   823
          (args, (pats, intro_t, ctxt)) = rewrite_arg' (t2, T2) (args, (pats, intro_t, ctxt))
bulwahn@39657
   824
          | rewrite_arg' (t, Type (@{type_name Product_Type.prod}, [T1, T2])) (args, (pats, intro_t, ctxt)) =
bulwahn@39657
   825
            let
bulwahn@39657
   826
              val thy = ProofContext.theory_of ctxt
bulwahn@39657
   827
              val ([x, y], ctxt') = Variable.variant_fixes ["x", "y"] ctxt
bulwahn@39657
   828
              val pat = (t, HOLogic.mk_prod (Free (x, T1), Free (y, T2)))
bulwahn@39657
   829
              val intro_t' = Pattern.rewrite_term thy [pat] [] intro_t
bulwahn@39657
   830
              val args' = map (Pattern.rewrite_term thy [pat] []) args
bulwahn@39657
   831
            in
bulwahn@39657
   832
              rewrite_arg' (Free (y, T2), T2) (args', (pat::pats, intro_t', ctxt'))
bulwahn@39657
   833
            end
bulwahn@39657
   834
          | rewrite_arg' _ (args, (pats, intro_t, ctxt)) = (args, (pats, intro_t, ctxt))
bulwahn@39657
   835
        val (args', (pats, intro_t', ctxt')) = rewrite_arg' (arg, fastype_of arg)
bulwahn@39657
   836
          (args, (pats, intro_t, ctxt))
bulwahn@39657
   837
      in
bulwahn@39657
   838
        rewrite_args args' (pats, intro_t', ctxt')
bulwahn@39657
   839
      end
bulwahn@39657
   840
  | _ => rewrite_args args (pats, intro_t, ctxt))
bulwahn@39657
   841
bulwahn@39657
   842
fun rewrite_prem atom =
bulwahn@39657
   843
  let
bulwahn@39657
   844
    val (_, args) = strip_comb atom
bulwahn@39657
   845
  in rewrite_args args end
bulwahn@39657
   846
bulwahn@39787
   847
fun split_conjuncts_in_assms ctxt th =
bulwahn@39787
   848
  let
bulwahn@39787
   849
    val ((_, [fixed_th]), ctxt') = Variable.import false [th] ctxt 
bulwahn@39787
   850
    fun split_conjs i nprems th =
bulwahn@39787
   851
      if i > nprems then th
bulwahn@39787
   852
      else
bulwahn@39787
   853
        case try Drule.RSN (@{thm conjI}, (i, th)) of
bulwahn@39787
   854
          SOME th' => split_conjs i (nprems+1) th'
bulwahn@39787
   855
        | NONE => split_conjs (i+1) nprems th
bulwahn@39787
   856
  in
bulwahn@39787
   857
    singleton (Variable.export ctxt' ctxt) (split_conjs 1 (Thm.nprems_of fixed_th) fixed_th)
bulwahn@39787
   858
  end
bulwahn@40052
   859
bulwahn@40052
   860
fun dest_conjunct_prem th =
bulwahn@40052
   861
  case HOLogic.dest_Trueprop (prop_of th) of
bulwahn@40052
   862
    (Const (@{const_name HOL.conj}, _) $ t $ t') =>
bulwahn@40052
   863
      dest_conjunct_prem (th RS @{thm conjunct1})
bulwahn@40052
   864
        @ dest_conjunct_prem (th RS @{thm conjunct2})
bulwahn@40052
   865
    | _ => [th]
bulwahn@40052
   866
bulwahn@33250
   867
fun expand_tuples thy intro =
bulwahn@33250
   868
  let
wenzelm@36610
   869
    val ctxt = ProofContext.init_global thy
bulwahn@33250
   870
    val (((T_insts, t_insts), [intro']), ctxt1) = Variable.import false [intro] ctxt
bulwahn@33250
   871
    val intro_t = prop_of intro'
bulwahn@33250
   872
    val concl = Logic.strip_imp_concl intro_t
bulwahn@33250
   873
    val (p, args) = strip_comb (HOLogic.dest_Trueprop concl)
bulwahn@33250
   874
    val (pats', intro_t', ctxt2) = rewrite_args args ([], intro_t, ctxt1)
bulwahn@33250
   875
    val (pats', intro_t', ctxt3) = 
bulwahn@33250
   876
      fold_atoms rewrite_prem intro_t' (pats', intro_t', ctxt2)
bulwahn@33250
   877
    fun rewrite_pat (ct1, ct2) =
bulwahn@33250
   878
      (ct1, cterm_of thy (Pattern.rewrite_term thy pats' [] (term_of ct2)))
bulwahn@33250
   879
    val t_insts' = map rewrite_pat t_insts
bulwahn@33250
   880
    val intro'' = Thm.instantiate (T_insts, t_insts') intro
bulwahn@33250
   881
    val [intro'''] = Variable.export ctxt3 ctxt [intro'']
bulwahn@33250
   882
    val intro'''' = Simplifier.full_simplify
bulwahn@33250
   883
      (HOL_basic_ss addsimps [@{thm fst_conv}, @{thm snd_conv}, @{thm Pair_eq}])
bulwahn@33250
   884
      intro'''
bulwahn@33250
   885
    (* splitting conjunctions introduced by Pair_eq*)
bulwahn@39787
   886
    val intro''''' = split_conjuncts_in_assms ctxt intro''''
bulwahn@33250
   887
  in
bulwahn@33250
   888
    intro'''''
bulwahn@33250
   889
  end
bulwahn@33250
   890
bulwahn@39802
   891
(** making case distributivity rules **)
bulwahn@39802
   892
(*** this should be part of the datatype package ***)
bulwahn@39802
   893
bulwahn@39802
   894
fun datatype_names_of_case_name thy case_name =
bulwahn@39802
   895
  map (#1 o #2) (#descr (the (Datatype_Data.info_of_case thy case_name)))
bulwahn@39802
   896
bulwahn@39802
   897
fun make_case_distribs new_type_names descr sorts thy =
bulwahn@39802
   898
  let
bulwahn@39802
   899
    val case_combs = Datatype_Prop.make_case_combs new_type_names descr sorts thy "f";
bulwahn@39802
   900
    fun make comb =
bulwahn@39802
   901
      let
bulwahn@39802
   902
        val Type ("fun", [T, T']) = fastype_of comb;
bulwahn@39802
   903
        val (Const (case_name, _), fs) = strip_comb comb
bulwahn@39802
   904
        val used = Term.add_tfree_names comb []
bulwahn@39802
   905
        val U = TFree (Name.variant used "'t", HOLogic.typeS)
bulwahn@39802
   906
        val x = Free ("x", T)
bulwahn@39802
   907
        val f = Free ("f", T' --> U)
bulwahn@39802
   908
        fun apply_f f' =
bulwahn@39802
   909
          let
bulwahn@39802
   910
            val Ts = binder_types (fastype_of f')
bulwahn@39802
   911
            val bs = map Bound ((length Ts - 1) downto 0)
bulwahn@39802
   912
          in
bulwahn@39802
   913
            fold (curry absdummy) (rev Ts) (f $ (list_comb (f', bs)))
bulwahn@39802
   914
          end
bulwahn@39802
   915
        val fs' = map apply_f fs
bulwahn@39802
   916
        val case_c' = Const (case_name, (map fastype_of fs') @ [T] ---> U)
bulwahn@39802
   917
      in
bulwahn@39802
   918
        HOLogic.mk_eq (f $ (comb $ x), list_comb (case_c', fs') $ x)
bulwahn@39802
   919
      end
bulwahn@39802
   920
  in
bulwahn@39802
   921
    map make case_combs
bulwahn@39802
   922
  end
bulwahn@39802
   923
bulwahn@39802
   924
fun case_rewrites thy Tcon =
bulwahn@39802
   925
  let
bulwahn@39802
   926
    val info = Datatype.the_info thy Tcon
bulwahn@39802
   927
    val descr = #descr info
bulwahn@39802
   928
    val sorts = #sorts info
bulwahn@39802
   929
    val typ_names = the_default [Tcon] (#alt_names info)
bulwahn@39802
   930
  in
bulwahn@39802
   931
    map (Drule.export_without_context o Skip_Proof.make_thm thy o HOLogic.mk_Trueprop)
bulwahn@39802
   932
      (make_case_distribs typ_names [descr] sorts thy)
bulwahn@39802
   933
  end
bulwahn@39802
   934
bulwahn@39802
   935
fun instantiated_case_rewrites thy Tcon =
bulwahn@39802
   936
  let
bulwahn@39802
   937
    val rew_ths = case_rewrites thy Tcon
bulwahn@39802
   938
    val ctxt = ProofContext.init_global thy
bulwahn@39802
   939
    fun instantiate th =
bulwahn@39802
   940
    let
bulwahn@39802
   941
      val f = (fst (strip_comb (fst (HOLogic.dest_eq (HOLogic.dest_Trueprop (prop_of th))))))
bulwahn@39802
   942
      val Type ("fun", [uninst_T, uninst_T']) = fastype_of f
bulwahn@39802
   943
      val ([tname, tname', uname, yname], ctxt') = Variable.add_fixes ["'t", "'t'", "'u", "y"] ctxt
bulwahn@39802
   944
      val T = TFree (tname, HOLogic.typeS)
bulwahn@39802
   945
      val T' = TFree (tname', HOLogic.typeS)
bulwahn@39802
   946
      val U = TFree (uname, HOLogic.typeS)
bulwahn@39802
   947
      val y = Free (yname, U)
bulwahn@39802
   948
      val f' = absdummy (U --> T', Bound 0 $ y)
bulwahn@39802
   949
      val th' = Thm.certify_instantiate
bulwahn@39802
   950
        ([(dest_TVar uninst_T, U --> T'), (dest_TVar uninst_T', T')],
bulwahn@39802
   951
         [((fst (dest_Var f), (U --> T') --> T'), f')]) th
bulwahn@39802
   952
      val [th'] = Variable.export ctxt' ctxt [th']
bulwahn@39802
   953
   in
bulwahn@39802
   954
     th'
bulwahn@39802
   955
   end
bulwahn@39802
   956
 in
bulwahn@39802
   957
   map instantiate rew_ths
bulwahn@39802
   958
 end
bulwahn@39802
   959
bulwahn@39802
   960
fun case_betapply thy t =
bulwahn@39802
   961
  let
bulwahn@39802
   962
    val case_name = fst (dest_Const (fst (strip_comb t)))
bulwahn@39802
   963
    val Tcons = datatype_names_of_case_name thy case_name
bulwahn@39802
   964
    val ths = maps (instantiated_case_rewrites thy) Tcons
bulwahn@39802
   965
  in
bulwahn@39802
   966
    MetaSimplifier.rewrite_term thy
bulwahn@39802
   967
      (map (fn th => th RS @{thm eq_reflection}) ths) [] t
bulwahn@39802
   968
  end
bulwahn@39802
   969
bulwahn@39657
   970
(*** conversions ***)
bulwahn@39657
   971
bulwahn@39657
   972
fun imp_prems_conv cv ct =
bulwahn@39657
   973
  case Thm.term_of ct of
bulwahn@39657
   974
    Const ("==>", _) $ _ $ _ => Conv.combination_conv (Conv.arg_conv cv) (imp_prems_conv cv) ct
bulwahn@39657
   975
  | _ => Conv.all_conv ct
bulwahn@39657
   976
bulwahn@39657
   977
fun all_params_conv cv ctxt ct =
bulwahn@39657
   978
  if Logic.is_all (Thm.term_of ct)
bulwahn@39657
   979
  then Conv.arg_conv (Conv.abs_conv (all_params_conv cv o #2) ctxt) ct
bulwahn@39657
   980
  else cv ctxt ct;
bulwahn@39657
   981
  
bulwahn@36047
   982
(** eta contract higher-order arguments **)
bulwahn@35875
   983
bulwahn@35875
   984
fun eta_contract_ho_arguments thy intro =
bulwahn@35875
   985
  let
bulwahn@35875
   986
    fun f atom = list_comb (apsnd ((map o map_products) Envir.eta_contract) (strip_comb atom))
bulwahn@35875
   987
  in
bulwahn@35875
   988
    map_term thy (map_concl f o map_atoms f) intro
bulwahn@35875
   989
  end
bulwahn@35875
   990
bulwahn@36047
   991
(** remove equalities **)
bulwahn@36022
   992
bulwahn@36022
   993
fun remove_equalities thy intro =
bulwahn@36022
   994
  let
bulwahn@36022
   995
    fun remove_eqs intro_t =
bulwahn@36022
   996
      let
bulwahn@36022
   997
        val (prems, concl) = Logic.strip_horn intro_t
bulwahn@36022
   998
        fun remove_eq (prems, concl) =
bulwahn@36022
   999
          let
bulwahn@36022
  1000
            fun removable_eq prem =
bulwahn@36022
  1001
              case try (HOLogic.dest_eq o HOLogic.dest_Trueprop) prem of
bulwahn@36022
  1002
                SOME (lhs, rhs) => (case lhs of
bulwahn@36022
  1003
                  Var _ => true
bulwahn@36022
  1004
                  | _ => (case rhs of Var _ => true | _ => false))
bulwahn@36022
  1005
              | NONE => false
bulwahn@36022
  1006
          in
bulwahn@36022
  1007
            case find_first removable_eq prems of
bulwahn@36022
  1008
              NONE => (prems, concl)
bulwahn@36022
  1009
            | SOME eq =>
bulwahn@36022
  1010
              let
bulwahn@36022
  1011
                val (lhs, rhs) = HOLogic.dest_eq (HOLogic.dest_Trueprop eq)
bulwahn@36022
  1012
                val prems' = remove (op =) eq prems
bulwahn@36022
  1013
                val subst = (case lhs of
bulwahn@36022
  1014
                  (v as Var _) =>
bulwahn@36022
  1015
                    (fn t => if t = v then rhs else t)
bulwahn@36022
  1016
                | _ => (case rhs of
bulwahn@36022
  1017
                   (v as Var _) => (fn t => if t = v then lhs else t)))
bulwahn@36022
  1018
              in
bulwahn@36022
  1019
                remove_eq (map (map_aterms subst) prems', map_aterms subst concl)
bulwahn@36022
  1020
              end
bulwahn@36022
  1021
          end
bulwahn@36022
  1022
      in
bulwahn@36022
  1023
        Logic.list_implies (remove_eq (prems, concl))
bulwahn@36022
  1024
      end
bulwahn@36022
  1025
  in
bulwahn@36022
  1026
    map_term thy remove_eqs intro
bulwahn@36022
  1027
  end
bulwahn@35875
  1028
bulwahn@36246
  1029
(* Some last processing *)
bulwahn@36246
  1030
bulwahn@36246
  1031
fun remove_pointless_clauses intro =
bulwahn@36246
  1032
  if Logic.strip_imp_prems (prop_of intro) = [@{prop "False"}] then
bulwahn@36246
  1033
    []
bulwahn@36246
  1034
  else [intro]
bulwahn@36246
  1035
bulwahn@36246
  1036
(* some peephole optimisations *)
bulwahn@36246
  1037
bulwahn@36246
  1038
fun peephole_optimisation thy intro =
bulwahn@36246
  1039
  let
wenzelm@36610
  1040
    val process =
wenzelm@36610
  1041
      MetaSimplifier.rewrite_rule (Predicate_Compile_Simps.get (ProofContext.init_global thy))
bulwahn@36246
  1042
    fun process_False intro_t =
bulwahn@36246
  1043
      if member (op =) (Logic.strip_imp_prems intro_t) @{prop "False"} then NONE else SOME intro_t
bulwahn@36246
  1044
    fun process_True intro_t =
bulwahn@36246
  1045
      map_filter_premises (fn p => if p = @{prop True} then NONE else SOME p) intro_t
bulwahn@36246
  1046
  in
bulwahn@36246
  1047
    Option.map (Skip_Proof.make_thm thy)
bulwahn@36246
  1048
      (process_False (process_True (prop_of (process intro))))
bulwahn@36246
  1049
  end
bulwahn@36246
  1050
bulwahn@39541
  1051
(* defining a quickcheck predicate *)
bulwahn@39541
  1052
bulwahn@39541
  1053
fun strip_imp_prems (Const(@{const_name HOL.implies}, _) $ A $ B) = A :: strip_imp_prems B
bulwahn@39541
  1054
  | strip_imp_prems _ = [];
bulwahn@39541
  1055
bulwahn@39541
  1056
fun strip_imp_concl (Const(@{const_name HOL.implies}, _) $ A $ B) = strip_imp_concl B
bulwahn@39541
  1057
  | strip_imp_concl A = A : term;
bulwahn@39541
  1058
bulwahn@39541
  1059
fun strip_horn A = (strip_imp_prems A, strip_imp_concl A);
bulwahn@39541
  1060
bulwahn@39541
  1061
fun define_quickcheck_predicate t thy =
bulwahn@39541
  1062
  let
bulwahn@39541
  1063
    val (vs, t') = strip_abs t
bulwahn@39541
  1064
    val vs' = Variable.variant_frees (ProofContext.init_global thy) [] vs
bulwahn@39541
  1065
    val t'' = subst_bounds (map Free (rev vs'), t')
bulwahn@39541
  1066
    val (prems, concl) = strip_horn t''
bulwahn@39541
  1067
    val constname = "quickcheck"
bulwahn@39541
  1068
    val full_constname = Sign.full_bname thy constname
bulwahn@39541
  1069
    val constT = map snd vs' ---> @{typ bool}
bulwahn@39541
  1070
    val thy1 = Sign.add_consts_i [(Binding.name constname, constT, NoSyn)] thy
bulwahn@39541
  1071
    val const = Const (full_constname, constT)
bulwahn@39541
  1072
    val t = Logic.list_implies
bulwahn@39541
  1073
      (map HOLogic.mk_Trueprop (prems @ [HOLogic.mk_not concl]),
bulwahn@39541
  1074
       HOLogic.mk_Trueprop (list_comb (const, map Free vs')))
bulwahn@39541
  1075
    val tac = fn _ => Skip_Proof.cheat_tac thy1
bulwahn@39541
  1076
    val intro = Goal.prove (ProofContext.init_global thy1) (map fst vs') [] t tac
bulwahn@39541
  1077
  in
bulwahn@39541
  1078
    ((((full_constname, constT), vs'), intro), thy1)
bulwahn@39541
  1079
  end
bulwahn@39541
  1080
bulwahn@33250
  1081
end;