Datasets:

hoskinson-center
/

proof-pile

	(*
	(C) Copyright Andreas Viktor Hess, DTU, 2020
	(C) Copyright Sebastian A. Mödersheim, DTU, 2020
	(C) Copyright Achim D. Brucker, University of Exeter, 2020
	(C) Copyright Anders Schlichtkrull, DTU, 2020

	All Rights Reserved.

	Redistribution and use in source and binary forms, with or without
	modification, are permitted provided that the following conditions are
	met:

	- Redistributions of source code must retain the above copyright
	notice, this list of conditions and the following disclaimer.

	- Redistributions in binary form must reproduce the above copyright
	notice, this list of conditions and the following disclaimer in the
	documentation and/or other materials provided with the distribution.

	- Neither the name of the copyright holder nor the names of its
	contributors may be used to endorse or promote products
	derived from this software without specific prior written
	permission.

	THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	"AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
	A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
	OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
	SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
	LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
	DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*)

	(* Title: trac.thy
	Author: Andreas Viktor Hess, DTU
	Author: Sebastian A. Mödersheim, DTU
	Author: Achim D. Brucker, University of Exeter
	Author: Anders Schlichtkrull, DTU
	*)

	section\<open>Support for the Trac Format\<close>
	theory
	"trac"
	imports
	trac_fp_parser
	trac_protocol_parser
	keywords
	"trac" :: thy_decl
	and "trac_import" :: thy_decl
	and "trac_trac" :: thy_decl
	and "trac_import_trac" :: thy_decl
	and "protocol_model_setup" :: thy_decl
	and "protocol_security_proof" :: thy_decl
	and "manual_protocol_model_setup" :: thy_decl
	and "manual_protocol_security_proof" :: thy_decl
	and "compute_fixpoint" :: thy_decl
	and "compute_SMP" :: thy_decl
	and "setup_protocol_model'" :: thy_decl
	and "protocol_security_proof'" :: thy_decl
	and "setup_protocol_checks" :: thy_decl
	begin

	ML \<open>
	(* Some of this is based on code from the following files distributed with Isabelle 2018:
	* HOL/Tools/value_command.ML
	* HOL/Code_Evaluation.thy
	* Pure.thy
	*)

	fun protocol_model_interpretation_defs name =
	let
	fun f s =
	(Binding.empty_atts:Attrib.binding, ((Binding.name s, NoSyn), name ^ "." ^ s))
	in
	(map f [
	"public", "arity", "Ana", "\<Gamma>", "\<Gamma>\<^sub>v", "timpls_transformable_to", "intruder_synth_mod_timpls",
	"analyzed_closed_mod_timpls", "timpls_transformable_to'", "intruder_synth_mod_timpls'",
	"analyzed_closed_mod_timpls'", "admissible_transaction_terms", "admissible_transaction",
	"abs_substs_set", "abs_substs_fun", "in_trancl", "transaction_poschecks_comp",
	"transaction_negchecks_comp", "transaction_check_comp", "transaction_check",
	"transaction_check_pre", "transaction_check_post", "compute_fixpoint_fun'",
	"compute_fixpoint_fun", "attack_notin_fixpoint", "protocol_covered_by_fixpoint",
	"analyzed_fixpoint", "wellformed_protocol'", "wellformed_protocol", "wellformed_fixpoint",
	"wellformed_composable_protocols", "composable_protocols"
	]):string Interpretation.defines
	end

	fun protocol_model_interpretation_params name =
	let
	fun f s = name ^ "_" ^ s
	in
	map SOME [f "arity", "\<lambda>_. 0", f "public", f "Ana", f "\<Gamma>", "0::nat", "1::nat"]
	end

	fun declare_thm_attr attribute name print lthy =
	let
	val arg = [(Facts.named name, [[Token.make_string (attribute, Position.none)]])]
	val (_, lthy') = Specification.theorems_cmd "" [(Binding.empty_atts, arg)] [] print lthy
	in
	lthy'
	end

	fun declare_def_attr attribute name = declare_thm_attr attribute (name ^ "_def")

	val declare_code_eqn = declare_def_attr "code"

	val declare_protocol_check = declare_def_attr "protocol_checks"

	fun declare_protocol_checks print =
	declare_protocol_check "attack_notin_fixpoint" print #>
	declare_protocol_check "protocol_covered_by_fixpoint" print #>
	declare_protocol_check "analyzed_fixpoint" print #>
	declare_protocol_check "wellformed_protocol'" print #>
	declare_protocol_check "wellformed_protocol" print #>
	declare_protocol_check "wellformed_fixpoint" print #>
	declare_protocol_check "compute_fixpoint_fun" print

	fun eval_define (name, raw_t) lthy =
	let
	val t = Code_Evaluation.dynamic_value_strict lthy (Syntax.read_term lthy raw_t)
	val arg = ((Binding.name name, NoSyn), ((Binding.name (name ^ "_def"),[]), t))
	val (_, lthy') = Local_Theory.define arg lthy
	in
	(t, lthy')
	end

	fun eval_define_declare (name, raw_t) print =
	eval_define (name, raw_t) ##> declare_code_eqn name print

	val _ = Outer_Syntax.local_theory' @{command_keyword "compute_fixpoint"}
	"evaluate and define protocol fixpoint"
	(Parse.name -- Parse.name >> (fn (protocol, fixpoint) => fn print =>
	snd o eval_define_declare (fixpoint, "compute_fixpoint_fun " ^ protocol) print));

	val _ = Outer_Syntax.local_theory' @{command_keyword "compute_SMP"}
	"evaluate and define a finite representation of the sub-message patterns of a protocol"
	((Scan.optional (\<^keyword>\<open>[\<close> \|-- Parse.name --\| \<^keyword>\<open>]\<close>) "no_optimizations") --
	Parse.name -- Parse.name >> (fn ((opt,protocol), smp) => fn print =>
	let
	val rmd = "List.remdups"
	val f = "Stateful_Strands.trms_list\<^sub>s\<^sub>s\<^sub>t"
	val g =
	"(\<lambda>T. " ^ f ^ " T@map (pair' prot_fun.Pair) (Stateful_Strands.setops_list\<^sub>s\<^sub>s\<^sub>t T))"
	fun s trms =
	"(" ^ rmd ^ " (List.concat (List.map (" ^ trms ^
	" \<circ> Labeled_Strands.unlabel \<circ> transaction_strand) " ^ protocol ^ ")))"
	val opt1 = "remove_superfluous_terms \<Gamma>"
	val opt2 = "generalize_terms \<Gamma> is_Var"
	val gsmp_opt =
	"generalize_terms \<Gamma> (\<lambda>t. is_Var t \<and> t \<noteq> TAtom AttackType \<and> " ^
	"t \<noteq> TAtom SetType \<and> t \<noteq> TAtom OccursSecType \<and> \<not>is_Atom (the_Var t))"
	val smp_fun = "SMP0 Ana \<Gamma>"
	fun smp_fun' opts =
	"(\<lambda>T. let T' = (" ^ rmd ^ " \<circ> " ^ opts ^ " \<circ> " ^ smp_fun ^
	") T in List.map (\<lambda>t. t \<cdot> Typed_Model.var_rename (Typed_Model.max_var_set " ^
	"(Messages.fv\<^sub>s\<^sub>e\<^sub>t (set (T@T'))))) T')"
	val cmd =
	if opt = "no_optimizations" then smp_fun ^ " " ^ s f
	else if opt = "optimized"
	then smp_fun' (opt1 ^ " \<circ> " ^ opt2) ^ " " ^ s f
	else if opt = "GSMP"
	then smp_fun' (opt1 ^ " \<circ> " ^ gsmp_opt) ^ " " ^ s g
	else error ("Invalid option: " ^ opt)
	in
	snd o eval_define_declare (smp, cmd) print
	end));

	val _ = Outer_Syntax.local_theory' @{command_keyword "setup_protocol_checks"}
	"setup protocol checks"
	(Parse.name -- Parse.name >> (fn (protocol_model, protocol_name) => fn print =>
	let
	val a1 = "coverage_check_intro_lemmata"
	val a2 = "coverage_check_unfold_lemmata"
	val a3 = "coverage_check_unfold_protocol_lemma"
	in
	declare_protocol_checks print #>
	declare_thm_attr a1 (protocol_model ^ ".protocol_covered_by_fixpoint_intros") print #>
	declare_def_attr a2 (protocol_model ^ ".protocol_covered_by_fixpoint") print #>
	declare_def_attr a3 protocol_name print
	end
	));

	val _ =
	Outer_Syntax.local_theory_to_proof \<^command_keyword>\<open>setup_protocol_model'\<close>
	"prove interpretation of protocol model locale into global theory"
	(Parse.!!! (Parse.name -- Parse_Spec.locale_expression) >> (fn (prefix,expr) => fn lthy =>
	let
	fun f x y z = ([(x,(y,(Expression.Positional z,[])))],[])
	val (a,(b,c)) = nth (fst expr) 0
	val name = fst b
	val _ = case c of (Expression.Named [],[]) => () \| _ => error "Invalid arguments"
	val pexpr = f a b (protocol_model_interpretation_params prefix)
	val pdefs = protocol_model_interpretation_defs name
	in
	if name = ""
	then error "No name given"
	else Interpretation.global_interpretation_cmd pexpr pdefs lthy
	end));

	val _ =
	Outer_Syntax.local_theory_to_proof' \<^command_keyword>\<open>protocol_security_proof'\<close>
	"prove interpretation of secure protocol locale into global theory"
	(Parse.!!! (Parse.name -- Parse_Spec.locale_expression) >> (fn (prefix,expr) => fn print =>
	let
	fun f x y z = ([(x,(y,(Expression.Positional z,[])))],[])
	val (a,(b,c)) = nth (fst expr) 0
	val d = case c of (Expression.Positional ps,[]) => ps \| _ => error "Invalid arguments"
	val pexpr = f a b (protocol_model_interpretation_params prefix@d)
	in
	declare_protocol_checks print #> Interpretation.global_interpretation_cmd pexpr []
	end
	));
	\<close>

	ML\<open>
	structure ml_isar_wrapper = struct
	fun define_constant_definition (constname, trm) lthy =
	let
	val arg = ((Binding.name constname, NoSyn), ((Binding.name (constname^"_def"),[]), trm))
	val ((_, (_ , thm)), lthy') = Local_Theory.define arg lthy
	in
	(thm, lthy')
	end

	fun define_constant_definition' (constname, trm) print lthy =
	let
	val arg = ((Binding.name constname, NoSyn), ((Binding.name (constname^"_def"),[]), trm))
	val ((_, (_ , thm)), lthy') = Local_Theory.define arg lthy
	val lthy'' = declare_code_eqn constname print lthy'
	in
	(thm, lthy'')
	end

	fun define_simple_abbrev (constname, trm) lthy =
	let
	val arg = ((Binding.name constname, NoSyn), trm)
	val ((_, _), lthy') = Local_Theory.abbrev Syntax.mode_default arg lthy
	in
	lthy'
	end

	fun define_simple_type_synonym (name, typedecl) lthy =
	let
	val (_, lthy') = Typedecl.abbrev_global (Binding.name name, [], NoSyn) typedecl lthy
	in
	lthy'
	end

	fun define_simple_datatype (dt_tyargs, dt_name) constructors =
	let
	val options = Plugin_Name.default_filter
	fun lift_c (tyargs, name) = (((Binding.empty, Binding.name name), map (fn t => (Binding.empty, t)) tyargs), NoSyn)
	val c_spec = map lift_c constructors
	val datatyp = ((map (fn ty => (NONE, ty)) dt_tyargs, Binding.name dt_name), NoSyn)
	val dtspec =
	((options,false),
	[(((datatyp, c_spec), (Binding.empty, Binding.empty, Binding.empty)), [])])
	in
	BNF_FP_Def_Sugar.co_datatypes BNF_Util.Least_FP BNF_LFP.construct_lfp dtspec
	end

	fun define_simple_primrec pname precs lthy =
	let
	val rec_eqs = map (fn (lhs,rhs) => (((Binding.empty,[]), HOLogic.mk_Trueprop (HOLogic.mk_eq (lhs,rhs))),[],[])) precs
	in
	snd (BNF_LFP_Rec_Sugar.primrec false [] [(Binding.name pname, NONE, NoSyn)] rec_eqs lthy)
	end

	fun define_simple_fun pname precs lthy =
	let
	val rec_eqs = map (fn (lhs,rhs) => (((Binding.empty,[]), HOLogic.mk_Trueprop (HOLogic.mk_eq (lhs,rhs))),[],[])) precs
	in
	Function_Fun.add_fun [(Binding.name pname, NONE, NoSyn)] rec_eqs Function_Common.default_config lthy
	end

	fun prove_simple name stmt tactic lthy =
	let
	val thm = Goal.prove lthy [] [] stmt (tactic o #context)
	\|> Goal.norm_result lthy
	\|> Goal.check_finished lthy
	in
	lthy \|>
	snd o Local_Theory.note ((Binding.name name, []), [thm])
	end

	fun prove_state_simple method proof_state =
	Seq.the_result "error in proof state" ( (Proof.refine method proof_state))
	\|> Proof.global_done_proof

	end
	\<close>

	ML\<open>

	structure trac_definitorial_package = struct
	(* constant names *)
	open Trac_Utils
	val enum_constsN="enum_consts"
	val setsN="sets"
	val funN="fun"
	val atomN="atom"
	val arityN="arity"
	val publicN = "public"
	val gammaN = "\<Gamma>"
	val anaN = "Ana"
	val valN = "val"
	val timpliesN = "timplies"
	val occursN = "occurs"
	val enumN = "enum"
	val priv_fun_secN = "PrivFunSec"
	val secret_typeN = "SecretType"
	val enum_typeN = "EnumType"
	val other_pubconsts_typeN = "PubConstType"

	val types = [enum_typeN, secret_typeN]
	val special_funs = ["occurs", "zero", valN, priv_fun_secN]

	fun mk_listT T = Type ("List.list", [T])
	val mk_setT = HOLogic.mk_setT
	val boolT = HOLogic.boolT
	val natT = HOLogic.natT
	val mk_tupleT = HOLogic.mk_tupleT
	val mk_prodT = HOLogic.mk_prodT

	val mk_set = HOLogic.mk_set
	val mk_list = HOLogic.mk_list
	val mk_nat = HOLogic.mk_nat
	val mk_eq = HOLogic.mk_eq
	val mk_Trueprop = HOLogic.mk_Trueprop
	val mk_tuple = HOLogic.mk_tuple
	val mk_prod = HOLogic.mk_prod

	fun mkN (a,b) = a^"_"^b

	val info = Output.information

	fun rm_special_funs sel l = list_minus (list_rm_pair sel) l special_funs

	fun is_priv_fun (trac:TracProtocol.protocol) f = let
	val funs = #private (Option.valOf (#function_spec trac))
	in
	(* not (List.find (fn g => fst g = f) funs = NONE) *)
	List.exists (fn (g,n) => f = g andalso n <> "0") funs
	end

	fun full_name name lthy =
	Local_Theory.full_name lthy (Binding.name name)

	fun full_name' n (trac:TracProtocol.protocol) lthy = full_name (mkN (#name trac, n)) lthy

	fun mk_prot_type name targs (trac:TracProtocol.protocol) lthy =
	Term.Type (full_name' name trac lthy, targs)

	val enum_constsT = mk_prot_type enum_constsN []

	fun mk_enum_const a trac lthy =
	Term.Const (full_name' enum_constsN trac lthy ^ "." ^ a, enum_constsT trac lthy)

	val databaseT = mk_prot_type setsN []

	val funT = mk_prot_type funN []

	val atomT = mk_prot_type atomN []

	fun messageT (trac:TracProtocol.protocol) lthy =
	Term.Type ("Transactions.prot_term", [funT trac lthy, atomT trac lthy, databaseT trac lthy])

	fun message_funT (trac:TracProtocol.protocol) lthy =
	Term.Type ("Transactions.prot_fun", [funT trac lthy, atomT trac lthy, databaseT trac lthy])

	fun message_varT (trac:TracProtocol.protocol) lthy =
	Term.Type ("Transactions.prot_var", [funT trac lthy, atomT trac lthy, databaseT trac lthy])

	fun message_term_typeT (trc:TracProtocol.protocol) lthy =
	Term.Type ("Transactions.prot_term_type", [funT trc lthy, atomT trc lthy, databaseT trc lthy])

	fun message_atomT (trac:TracProtocol.protocol) lthy =
	Term.Type ("Transactions.prot_atom", [atomT trac lthy])

	fun messageT' varT (trac:TracProtocol.protocol) lthy =
	Term.Type ("Term.term", [message_funT trac lthy, varT])

	fun message_listT (trac:TracProtocol.protocol) lthy =
	mk_listT (messageT trac lthy)

	fun message_listT' varT (trac:TracProtocol.protocol) lthy =
	mk_listT (messageT' varT trac lthy)

	fun absT (trac:TracProtocol.protocol) lthy =
	mk_setT (databaseT trac lthy)

	fun abssT (trac:TracProtocol.protocol) lthy =
	mk_setT (absT trac lthy)

	val poscheckvariantT =
	Term.Type ("Strands_and_Constraints.poscheckvariant", [])

	val strand_labelT =
	Term.Type ("Labeled_Strands.strand_label", [natT])

	fun strand_stepT (trac:TracProtocol.protocol) lthy =
	Term.Type ("Stateful_Strands.stateful_strand_step",
	[message_funT trac lthy, message_varT trac lthy])

	fun labeled_strand_stepT (trac:TracProtocol.protocol) lthy =
	mk_prodT (strand_labelT, strand_stepT trac lthy)

	fun prot_strandT (trac:TracProtocol.protocol) lthy =
	mk_listT (labeled_strand_stepT trac lthy)

	fun prot_transactionT (trac:TracProtocol.protocol) lthy =
	Term.Type ("Transactions.prot_transaction",
	[funT trac lthy, atomT trac lthy, databaseT trac lthy, natT])

	val mk_star_label =
	Term.Const ("Labeled_Strands.strand_label.LabelS", strand_labelT)

	fun mk_prot_label (lbl:int) =
	Term.Const ("Labeled_Strands.strand_label.LabelN", natT --> strand_labelT) $
	mk_nat lbl

	fun mk_labeled_step (label:term) (step:term) =
	mk_prod (label, step)

	fun mk_Send_step (trac:TracProtocol.protocol) lthy (label:term) (msg:term) =
	mk_labeled_step label
	(Term.Const ("Stateful_Strands.stateful_strand_step.Send",
	messageT trac lthy --> strand_stepT trac lthy) $ msg)

	fun mk_Receive_step (trac:TracProtocol.protocol) lthy (label:term) (msg:term) =
	mk_labeled_step label
	(Term.Const ("Stateful_Strands.stateful_strand_step.Receive",
	messageT trac lthy --> strand_stepT trac lthy) $ msg)

	fun mk_InSet_step (trac:TracProtocol.protocol) lthy (label:term) (elem:term) (set:term) =
	let
	val psT = [poscheckvariantT, messageT trac lthy, messageT trac lthy]
	in
	mk_labeled_step label
	(Term.Const ("Stateful_Strands.stateful_strand_step.InSet",
	psT ---> strand_stepT trac lthy) $
	Term.Const ("Strands_and_Constraints.poscheckvariant.Check", poscheckvariantT) $
	elem $ set)
	end

	fun mk_NotInSet_step (trac:TracProtocol.protocol) lthy (label:term) (elem:term) (set:term) =
	let
	val varT = message_varT trac lthy
	val trm_prodT = mk_prodT (messageT trac lthy, messageT trac lthy)
	val psT = [mk_listT varT, mk_listT trm_prodT, mk_listT trm_prodT]
	in
	mk_labeled_step label
	(Term.Const ("Stateful_Strands.stateful_strand_step.NegChecks",
	psT ---> strand_stepT trac lthy) $
	mk_list varT [] $
	mk_list trm_prodT [] $
	mk_list trm_prodT [mk_prod (elem,set)])
	end

	fun mk_Inequality_step (trac:TracProtocol.protocol) lthy (label:term) (t1:term) (t2:term) =
	let
	val varT = message_varT trac lthy
	val trm_prodT = mk_prodT (messageT trac lthy, messageT trac lthy)
	val psT = [mk_listT varT, mk_listT trm_prodT, mk_listT trm_prodT]
	in
	mk_labeled_step label
	(Term.Const ("Stateful_Strands.stateful_strand_step.NegChecks",
	psT ---> strand_stepT trac lthy) $
	mk_list varT [] $
	mk_list trm_prodT [mk_prod (t1,t2)] $
	mk_list trm_prodT [])
	end

	fun mk_Insert_step (trac:TracProtocol.protocol) lthy (label:term) (elem:term) (set:term) =
	mk_labeled_step label
	(Term.Const ("Stateful_Strands.stateful_strand_step.Insert",
	[messageT trac lthy, messageT trac lthy] ---> strand_stepT trac lthy) $
	elem $ set)

	fun mk_Delete_step (trac:TracProtocol.protocol) lthy (label:term) (elem:term) (set:term) =
	mk_labeled_step label
	(Term.Const ("Stateful_Strands.stateful_strand_step.Delete",
	[messageT trac lthy, messageT trac lthy] ---> strand_stepT trac lthy) $
	elem $ set)

	fun mk_Transaction (trac:TracProtocol.protocol) lthy S1 S2 S3 S4 S5 S6 =
	let
	val varT = message_varT trac lthy
	val msgT = messageT trac lthy
	val var_listT = mk_listT varT
	val msg_listT = mk_listT msgT
	val trT = prot_transactionT trac lthy
	(* val decl_elemT = mk_prodT (varT, mk_listT msgT)
	val declT = mk_listT decl_elemT *)
	val stepT = labeled_strand_stepT trac lthy
	val strandT = prot_strandT trac lthy
	val strandsT = mk_listT strandT
	val paramsT = [(* declT, *)var_listT, strandT, strandT, strandT, strandT, strandT]
	in
	Term.Const ("Transactions.prot_transaction.Transaction", paramsT ---> trT) $
	(* mk_list decl_elemT [] $ *)
	(if null S4 then mk_list varT []
	else (Term.Const (@{const_name "map"}, [msgT --> varT, msg_listT] ---> var_listT) $
	Term.Const (@{const_name "the_Var"}, msgT --> varT) $
	mk_list msgT S4)) $
	mk_list stepT S1 $
	mk_list stepT [] $
	(if null S3 then mk_list stepT S2
	else (Term.Const (@{const_name "append"}, [strandT,strandT] ---> strandT) $
	mk_list stepT S2 $
	(Term.Const (@{const_name "concat"}, strandsT --> strandT) $ mk_list strandT S3))) $
	mk_list stepT S5 $
	mk_list stepT S6
	end

	fun get_funs (trac:TracProtocol.protocol) =
	let
	fun append_sec fs = fs@[(priv_fun_secN, "0")]
	val filter_funs = filter (fn (_,n) => n <> "0")
	val filter_consts = filter (fn (_,n) => n = "0")
	fun inc_ar (s,n) = (s, Int.toString (1+Option.valOf (Int.fromString n)))
	in
	case (#function_spec trac) of
	NONE => ([],[],[])
	\| SOME ({public=pub, private=priv}) =>
	let
	val pub_symbols = rm_special_funs fst (pub@map inc_ar (filter_funs priv))
	val pub_funs = filter_funs pub_symbols
	val pub_consts = filter_consts pub_symbols
	val priv_consts = append_sec (rm_special_funs fst (filter_consts priv))
	in
	(pub_funs, pub_consts, priv_consts)
	end
	end

	fun get_set_spec (trac:TracProtocol.protocol) =
	mk_unique (map (fn (s,n) => (s,Option.valOf (Int.fromString n))) (#set_spec trac))

	fun set_arity (trac:TracProtocol.protocol) s =
	case List.find (fn x => fst x = s) (get_set_spec trac) of
	SOME (_,n) => SOME n
	\| NONE => NONE

	fun get_enums (trac:TracProtocol.protocol) =
	mk_unique (TracProtocol.extract_Consts (#type_spec trac))

	fun flatten_type_spec (trac:TracProtocol.protocol) =
	let
	fun find_type taus tau =
	case List.find (fn x => fst x = tau) taus of
	SOME x => snd x
	\| NONE => error ("Type " ^ tau ^ " has not been declared")
	fun step taus (s,e) =
	case e of
	TracProtocol.Union ts =>
	let
	val es = map (find_type taus) ts
	fun f es' = mk_unique (List.concat (map TracProtocol.the_Consts es'))
	in
	if List.all TracProtocol.is_Consts es
	then (s,TracProtocol.Consts (f es))
	else (s,TracProtocol.Union ts)
	end
	\| c => (s,c)
	fun loop taus =
	let
	val taus' = map (step taus) taus
	in
	if taus = taus'
	then taus
	else loop taus'
	end
	val flat_type_spec =
	let
	val x = loop (#type_spec trac)
	val errpre = "Couldn't flatten the enumeration types: "
	in
	if List.all (fn (_,e) => TracProtocol.is_Consts e) x
	then
	let
	val y = map (fn (s,e) => (s,TracProtocol.the_Consts e)) x
	in
	if List.all (not o List.null o snd) y
	then y
	else error (errpre ^ "does every type have at least one value?")
	end
	else error (errpre ^ "have all types been declared?")
	end
	in
	flat_type_spec
	end

	fun is_attack_transaction (tr:TracProtocol.cTransaction) =
	not (null (#attack_actions tr))

	fun get_transaction_name (tr:TracProtocol.cTransaction) =
	#1 (#transaction tr)

	fun get_fresh_value_variables (tr:TracProtocol.cTransaction) =
	map_filter (TracProtocol.maybe_the_Fresh o snd) (#fresh_actions tr)

	fun get_nonfresh_value_variables (tr:TracProtocol.cTransaction) =
	map fst (filter (fn x => snd x = "value") (#2 (#transaction tr)))

	fun get_value_variables (tr:TracProtocol.cTransaction) =
	get_nonfresh_value_variables tr@get_fresh_value_variables tr

	fun get_enum_variables (tr:TracProtocol.cTransaction) =
	mk_unique (filter (fn x => snd x <> "value") (#2 (#transaction tr)))

	fun get_variable_restrictions (tr:TracProtocol.cTransaction) =
	let
	val enum_vars = get_enum_variables tr
	val value_vars = get_value_variables tr
	fun enum_member x = List.exists (fn y => x = fst y)
	fun value_member x = List.exists (fn y => x = y)
	fun aux [] = ([],[])
	\| aux ((a,b)::rs) =
	if enum_member a enum_vars andalso enum_member b enum_vars
	then let val (es,vs) = aux rs in ((a,b)::es,vs) end
	else if value_member a value_vars andalso value_member b value_vars
	then let val (es,vs) = aux rs in (es,(a,b)::vs) end
	else error ("Ill-formed or ill-typed variable restriction: " ^ a ^ " != " ^ b)
	in
	aux (#3 (#transaction tr))
	end

	fun conv_enum_consts trac (t:Trac_Term.cMsg) =
	let
	open Trac_Term
	val enums = get_enums trac
	fun aux (cFun (f,ts)) =
	if List.exists (fn x => x = f) enums
	then if null ts
	then cEnum f
	else error ("Enum constant " ^ f ^ " should not have a parameter list")
	else
	cFun (f,map aux ts)
	\| aux (cConst c) =
	if List.exists (fn x => x = c) enums
	then cEnum c
	else cConst c
	\| aux (cSet (s,ts)) = cSet (s,map aux ts)
	\| aux (cOccursFact bs) = cOccursFact (aux bs)
	\| aux t = t
	in
	aux t
	end

	fun val_to_abs_list vs =
	let
	open Trac_Term
	fun aux t = case t of cEnum b => b \| _ => error "Invalid val parameter list"
	in
	case vs of
	[] => []
	\| (cConst "0"::ts) => val_to_abs_list ts
	\| (cFun (s,ps)::ts) => (s, map aux ps)::val_to_abs_list ts
	\| (cSet (s,ps)::ts) => (s, map aux ps)::val_to_abs_list ts
	\| _ => error "Invalid val parameter list"
	end

	fun val_to_abs (t:Trac_Term.cMsg) =
	let
	open Trac_Term
	fun aux t = case t of cEnum b => b \| _ => error "Invalid val parameter list"

	fun val_to_abs_list [] = []
	\| val_to_abs_list (cConst "0"::ts) = val_to_abs_list ts
	\| val_to_abs_list (cFun (s,ps)::ts) = (s, map aux ps)::val_to_abs_list ts
	\| val_to_abs_list (cSet (s,ps)::ts) = (s, map aux ps)::val_to_abs_list ts
	\| val_to_abs_list _ = error "Invalid val parameter list"
	in
	case t of
	cFun (f,ts) =>
	if f = valN
	then cAbs (val_to_abs_list ts)
	else cFun (f,map val_to_abs ts)
	\| cSet (s,ts) =>
	cSet (s,map val_to_abs ts)
	\| cOccursFact bs =>
	cOccursFact (val_to_abs bs)
	\| t => t
	end

	fun occurs_enc t =
	let
	open Trac_Term
	fun aux [cVar x] = cVar x
	\| aux [cAbs bs] = cAbs bs
	\| aux _ = error "Invalid occurs parameter list"
	fun enc (cFun (f,ts)) = (
	if f = occursN
	then cOccursFact (aux ts)
	else cFun (f,map enc ts))
	\| enc (cSet (s,ts)) =
	cSet (s,map enc ts)
	\| enc (cOccursFact bs) =
	cOccursFact (enc bs)
	\| enc t = t
	in
	enc t
	end

	fun priv_fun_enc trac (Trac_Term.cFun (f,ts)) = (
	if is_priv_fun trac f andalso
	(case ts of Trac_Term.cPrivFunSec::_ => false \| _ => true)
	then Trac_Term.cFun (f,Trac_Term.cPrivFunSec::map (priv_fun_enc trac) ts)
	else Trac_Term.cFun (f,map (priv_fun_enc trac) ts))
	\| priv_fun_enc _ t = t

	fun transform_cMsg trac =
	priv_fun_enc trac o occurs_enc o val_to_abs o conv_enum_consts trac

	fun check_no_vars_and_consts (fp:Trac_Term.cMsg list) =
	let
	open Trac_Term
	fun aux (cVar _) = false
	\| aux (cConst _) = false
	\| aux (cFun (_,ts)) = List.all aux ts
	\| aux (cSet (_,ts)) = List.all aux ts
	\| aux (cOccursFact bs) = aux bs
	\| aux _ = true
	in
	if List.all aux fp
	then fp
	else error "There shouldn't be any cVars and cConsts at this point in the fixpoint translation"
	end

	fun split_fp (fp:Trac_Term.cMsg list) =
	let
	open Trac_Term
	fun fa t = case t of cFun (s,_) => s <> timpliesN \| _ => true
	fun fb (t,ts) = case t of cOccursFact (cAbs bs) => bs::ts \| _ => ts
	fun fc (cFun (s, [cAbs bs, cAbs cs]),ts) =
	if s = timpliesN
	then (bs,cs)::ts
	else ts
	\| fc (_,ts) = ts

	val eq = eq_set (fn ((s,xs),(t,ys)) => s = t andalso eq_set (op =) (xs,ys))
	fun eq_pairs ((a,b),(c,d)) = eq (a,c) andalso eq (b,d)

	val timplies_trancl =
	let
	fun trans_step ts =
	let
	fun aux (s,t) = map (fn (_,u) => (s,u)) (filter (fn (v,_) => eq (t,v)) ts)
	in
	distinct eq_pairs (filter (not o eq) (ts@List.concat (map aux ts)))
	end
	fun loop ts =
	let
	val ts' = trans_step ts
	in
	if eq_set eq_pairs (ts,ts')
	then ts
	else loop ts'
	end
	in
	loop
	end

	val ti = List.foldl fc [] fp
	in
	(filter fa fp, distinct eq (List.foldl fb [] fp@map snd ti), timplies_trancl ti)
	end

	fun mk_enum_substs trac (vars:(string * Trac_Term.VarType) list) =
	let
	open Trac_Term
	val flat_type_spec = flatten_type_spec trac
	val deltas =
	let
	fun f (s,EnumType tau) = (
	case List.find (fn x => fst x = tau) flat_type_spec of
	SOME x => map (fn c => (s,c)) (snd x)
	\| NONE => error ("Type " ^ tau ^ " was not found in the type specification"))
	\| f (s,_) = error ("Variable " ^ s ^ " is not of enum type")
	in
	list_product (map f vars)
	end
	in
	map (fn d => map (fn (x,t) => (x,cEnum t)) d) deltas
	end

	fun ground_enum_variables trac (fp:Trac_Term.cMsg list) =
	let
	open Trac_Term
	fun do_grounding t = map (fn d => subst_apply d t) (mk_enum_substs trac (fv_cMsg t))
	in
	List.concat (map do_grounding fp)
	end

	fun transform_fp trac (fp:Trac_Term.cMsg list) =
	fp \|> ground_enum_variables trac
	\|> map (transform_cMsg trac)
	\|> check_no_vars_and_consts
	\|> split_fp

	fun database_to_hol (db:string * Trac_Term.cMsg list) (trac:TracProtocol.protocol) lthy =
	let
	open Trac_Term
	val errmsg = "Invalid database parameter"
	fun mkN' n = mkN (#name trac, n)
	val s_prefix = full_name (mkN' setsN) lthy ^ "."
	val e_prefix = full_name (mkN' enum_constsN) lthy ^ "."
	val (s,es) = db
	val tau = enum_constsT trac lthy
	val databaseT = databaseT trac lthy
	val a = Term.Const (s_prefix ^ s, map (fn _ => tau) es ---> databaseT)
	fun param_to_hol (cVar (x,EnumType _)) = Term.Free (x, tau)
	\| param_to_hol (cVar (x,Untyped)) = Term.Free (x, tau)
	\| param_to_hol (cEnum e) = Term.Const (e_prefix ^ e, tau)
	\| param_to_hol (cConst c) = error (errmsg ^ ": cConst " ^ c)
	\| param_to_hol (cVar (x,ValueType)) = error (errmsg ^ ": cVar (" ^ x ^ ",ValueType)")
	\| param_to_hol _ = error errmsg
	in
	fold (fn e => fn b => b $ param_to_hol e) es a
	end

	fun abs_to_hol (bs:(string * string list) list) (trac:TracProtocol.protocol) lthy =
	let
	val databaseT = databaseT trac lthy
	fun db_params_to_cEnum (a,cs) = (a, map Trac_Term.cEnum cs)
	in
	mk_set databaseT (map (fn db => database_to_hol (db_params_to_cEnum db) trac lthy) bs)
	end

	fun cMsg_to_hol (t:Trac_Term.cMsg) lbl varT var_map free_enum_var trac lthy =
	let
	open Trac_Term
	val tT = messageT' varT trac lthy
	val fT = message_funT trac lthy
	val enum_constsT = enum_constsT trac lthy
	val tsT = message_listT' varT trac lthy
	val VarT = varT --> tT
	val FunT = [fT, tsT] ---> tT
	val absT = absT trac lthy
	val databaseT = databaseT trac lthy
	val AbsT = absT --> fT
	val funT = funT trac lthy
	val FuT = funT --> fT
	val SetT = databaseT --> fT
	val enumT = enum_constsT --> funT
	val VarC = Term.Const (@{const_name "Var"}, VarT)
	val FunC = Term.Const (@{const_name "Fun"}, FunT)
	val NilC = Term.Const (@{const_name "Nil"}, tsT)
	val prot_label = mk_nat lbl
	fun full_name'' n = full_name' n trac lthy
	fun mk_enum_const' a = mk_enum_const a trac lthy
	fun mk_prot_fun_trm f tau = Term.Const ("Transactions.prot_fun." ^ f, tau)
	fun mk_enum_trm etrm =
	mk_prot_fun_trm "Fu" FuT $ (Term.Const (full_name'' funN ^ "." ^ enumN, enumT) $ etrm)
	fun mk_Fu_trm f =
	mk_prot_fun_trm "Fu" FuT $ Term.Const (full_name'' funN ^ "." ^ f, funT)
	fun c_to_h s = cMsg_to_hol s lbl varT var_map free_enum_var trac lthy
	fun c_list_to_h ts = mk_list tT (map c_to_h ts)
	in
	case t of
	cVar x =>
	if free_enum_var x
	then FunC $ mk_enum_trm (Term.Free (fst x, enum_constsT)) $ NilC
	else VarC $ var_map x
	\| cConst f =>
	FunC $
	mk_Fu_trm f $
	NilC
	\| cFun (f,ts) =>
	FunC $
	mk_Fu_trm f $
	c_list_to_h ts
	\| cSet (s,ts) =>
	FunC $
	(mk_prot_fun_trm "Set" SetT $ database_to_hol (s,ts) trac lthy) $
	NilC
	\| cAttack =>
	FunC $
	(mk_prot_fun_trm "Attack" (natT --> fT) $ prot_label) $
	NilC
	\| cAbs bs =>
	FunC $
	(mk_prot_fun_trm "Abs" AbsT $ abs_to_hol bs trac lthy) $
	NilC
	\| cOccursFact bs =>
	FunC $
	mk_prot_fun_trm "OccursFact" fT $
	mk_list tT [
	FunC $ mk_prot_fun_trm "OccursSec" fT $ NilC,
	c_to_h bs]
	\| cPrivFunSec =>
	FunC $
	mk_Fu_trm priv_fun_secN $
	NilC
	\| cEnum a =>
	FunC $
	mk_enum_trm (mk_enum_const' a) $
	NilC
	end

	fun ground_cMsg_to_hol t lbl trac lthy =
	cMsg_to_hol t lbl (message_varT trac lthy) (fn _ => error "Term not ground")
	(fn _ => false) trac lthy

	fun ana_cMsg_to_hol inc_vars t (ana_var_map:string list) =
	let
	open Trac_Term
	fun var_map (x,Untyped) = (
	case list_find (fn y => x = y) ana_var_map of
	SOME (_,n) => if inc_vars then mk_nat (1+n) else mk_nat n
	\| NONE => error ("Analysis variable " ^ x ^ " not found"))
	\| var_map _ = error "Analysis variables must be untyped"
	val lbl = 0 (* There's no constants in analysis messages requiring labels anyway *)
	in
	cMsg_to_hol t lbl natT var_map (fn _ => false)
	end

	fun transaction_cMsg_to_hol t lbl (transaction_var_map:string list) trac lthy =
	let
	open Trac_Term
	val varT = message_varT trac lthy
	val atomT = message_atomT trac lthy
	val term_typeT = message_term_typeT trac lthy
	fun TAtom_Value_var n =
	let
	val a = Term.Const (@{const_name "Var"}, atomT --> term_typeT) $
	Term.Const ("Transactions.prot_atom.Value", atomT)
	in
	HOLogic.mk_prod (a, mk_nat n)
	end

	fun var_map_err_prefix x =
	"Transaction variable " ^ x ^ " should be value typed but is actually "

	fun var_map (x,ValueType) = (
	case list_find (fn y => x = y) transaction_var_map of
	SOME (_,n) => TAtom_Value_var n
	\| NONE => error ("Transaction variable " ^ x ^ " not found"))
	\| var_map (x,EnumType e) = error (var_map_err_prefix x ^ "of enum type " ^ e)
	\| var_map (x,Untyped) = error (var_map_err_prefix x ^ "untyped")
	in
	cMsg_to_hol t lbl varT var_map (fn (_,t) => case t of EnumType _ => true \| _ => false)
	trac lthy
	end

	fun fp_triple_to_hol (fp,occ,ti) trac lthy =
	let
	val prot_label = 0
	val tau_abs = absT trac lthy
	val tau_fp_elem = messageT trac lthy
	val tau_occ_elem = tau_abs
	val tau_ti_elem = mk_prodT (tau_abs, tau_abs)
	fun a_to_h bs = abs_to_hol bs trac lthy
	fun c_to_h t = ground_cMsg_to_hol t prot_label trac lthy
	val fp' = mk_list tau_fp_elem (map c_to_h fp)
	val occ' = mk_list tau_occ_elem (map a_to_h occ)
	val ti' = mk_list tau_ti_elem (map (mk_prod o map_prod a_to_h) ti)
	in
	mk_tuple [fp', occ', ti']
	end

	fun abstract_over_enum_vars enum_vars enum_ineqs trm flat_type_spec trac lthy =
	let
	val enum_constsT = enum_constsT trac lthy
	fun enumlistelemT n = mk_tupleT (replicate n enum_constsT)
	fun enumlistT n = mk_listT (enumlistelemT n)
	fun mk_enum_const' a = mk_enum_const a trac lthy

	fun absfreeprod xs trm =
	let
	val tau = enum_constsT
	val tau_out = Term.fastype_of trm
	fun absfree' x = absfree (x,enum_constsT)
	fun aux _ [] = trm
	\| aux _ [x] = absfree' x trm
	\| aux len (x::y::xs) =
	Term.Const (@{const_name "case_prod"},
	[[tau,mk_tupleT (replicate (len-1) tau)] ---> tau_out,
	mk_tupleT (replicate len tau)] ---> tau_out) $
	absfree' x (aux (len-1) (y::xs))
	in
	aux (length xs) xs
	end

	fun mk_enum_neq (a,b) = (HOLogic.mk_not o HOLogic.mk_eq)
	(Term.Free (a, enum_constsT), Term.Free (b, enum_constsT))

	fun mk_enum_neqs_list [] = Term.Const (@{const_name "True"}, HOLogic.boolT)
	\| mk_enum_neqs_list [x] = mk_enum_neq x
	\| mk_enum_neqs_list (x::y::xs) = HOLogic.mk_conj (mk_enum_neq x, mk_enum_neqs_list (y::xs))

	val enum_types =
	let
	fun aux t =
	if t = ""
	then get_enums trac
	else case List.find (fn (s,_) => t = s) flat_type_spec of
	SOME (_,cs) => cs
	\| NONE => error ("Not an enum type: " ^ t ^ "?")
	in
	map (aux o snd) enum_vars
	end

	val enumlist_product =
	let
	fun mk_enumlist ns = mk_list enum_constsT (map mk_enum_const' ns)

	fun aux _ [] = mk_enumlist []
	\| aux _ [ns] = mk_enumlist ns
	\| aux len (ns::ms::elists) =
	Term.Const ("List.product", [enumlistT 1, enumlistT (len-1)] ---> enumlistT len) $
	mk_enumlist ns $ aux (len-1) (ms::elists)
	in
	aux (length enum_types) enum_types
	end

	val absfp = absfreeprod (map fst enum_vars) trm
	val eptrm = enumlist_product
	val typof = Term.fastype_of
	val evseT = enumlistelemT (length enum_vars)
	val evslT = enumlistT (length enum_vars)
	val eneqs = absfreeprod (map fst enum_vars) (mk_enum_neqs_list enum_ineqs)
	in
	if null enum_vars
	then mk_list (typof trm) [trm]
	else if null enum_ineqs
	then Term.Const(@{const_name "map"},
	[typof absfp, typof eptrm] ---> mk_listT (typof trm)) $
	absfp $ eptrm
	else Term.Const(@{const_name "map"},
	[typof absfp, typof eptrm] ---> mk_listT (typof trm)) $
	absfp $ (Term.Const(@{const_name "filter"},
	[evseT --> HOLogic.boolT, evslT] ---> evslT) $
	eneqs $ eptrm)
	end

	fun mk_type_of_name lthy pname name ty_args
	= Type(Local_Theory.full_name lthy (Binding.name (mkN(pname, name))), ty_args)

	fun mk_mt_list t = Term.Const (@{const_name "Nil"}, mk_listT t)

	fun name_of_typ (Type (s, _)) = s
	\| name_of_typ (TFree _) = error "name_of_type: unexpected TFree"
	\| name_of_typ (TVar _ ) = error "name_of_type: unexpected TVAR"

	fun prove_UNIV name typ elems thmsN lthy =
	let
	val rhs = mk_set typ elems
	val lhs = Const("Set.UNIV",mk_setT typ)
	val stmt = mk_Trueprop (mk_eq (lhs,rhs))
	val fq_tname = name_of_typ typ

	fun inst_and_prove_enum thy =
	let
	val _ = writeln("Inst enum: "^name)
	val lthy = Class.instantiation ([fq_tname], [], @{sort enum}) thy
	val enum_eq = Const("Pure.eq",mk_listT typ --> mk_listT typ --> propT)
	$Const(@{const_name "enum_class.enum"},mk_listT typ)
	$(mk_list typ elems)

	val ((_, (_, enum_def')), lthy) = Specification.definition NONE [] []
	((Binding.name ("enum_"^name),[]), enum_eq) lthy
	val ctxt_thy = Proof_Context.init_global (Proof_Context.theory_of lthy)
	val enum_def = singleton (Proof_Context.export lthy ctxt_thy) enum_def'

	val enum_all_eq = Const("Pure.eq", boolT --> boolT --> propT)
	$(Const(@{const_name "enum_class.enum_all"},(typ --> boolT) --> boolT)
	$Free("P",typ --> boolT))
	$(Const(@{const_name "list_all"},(typ --> boolT) --> (mk_listT typ) --> boolT)
	$Free("P",typ --> boolT)$(mk_list typ elems))
	val ((_, (_, enum_all_def')), lthy) = Specification.definition NONE [] []
	((Binding.name ("enum_all_"^name),[]), enum_all_eq) lthy
	val ctxt_thy = Proof_Context.init_global (Proof_Context.theory_of lthy)
	val enum_all_def = singleton (Proof_Context.export lthy ctxt_thy) enum_all_def'

	val enum_ex_eq = Const("Pure.eq", boolT --> boolT --> propT)
	$(Const(@{const_name "enum_class.enum_ex"},(typ --> boolT) --> boolT)
	$Free("P",typ --> boolT))
	$(Const(@{const_name "list_ex"},(typ --> boolT) --> (mk_listT typ) --> boolT)
	$Free("P",typ --> boolT)$(mk_list typ elems))
	val ((_, (_, enum_ex_def')), lthy) = Specification.definition NONE [] []
	((Binding.name ("enum_ex_"^name),[]), enum_ex_eq) lthy
	val ctxt_thy = Proof_Context.init_global (Proof_Context.theory_of lthy)
	val enum_ex_def = singleton (Proof_Context.export lthy ctxt_thy) enum_ex_def'
	in
	Class.prove_instantiation_exit (fn ctxt =>
	(Class.intro_classes_tac ctxt []) THEN
	ALLGOALS (simp_tac (ctxt addsimps [Proof_Context.get_thm ctxt (name^"_UNIV"),
	enum_def, enum_all_def, enum_ex_def]) )
	)lthy
	end
	fun inst_and_prove_finite thy =
	let
	val lthy = Class.instantiation ([fq_tname], [], @{sort finite}) thy
	in
	Class.prove_instantiation_exit (fn ctxt =>
	(Class.intro_classes_tac ctxt []) THEN
	(simp_tac (ctxt addsimps[Proof_Context.get_thm ctxt (name^"_UNIV")])) 1) lthy
	end
	in
	lthy
	\|> ml_isar_wrapper.prove_simple (name^"_UNIV") stmt
	(fn c => (safe_tac c)
	THEN (ALLGOALS(simp_tac c))
	THEN (ALLGOALS(Metis_Tactic.metis_tac ["full_types"]
	"combs" c
	(map (Proof_Context.get_thm c) thmsN)))
	)
	\|> Local_Theory.raw_theory inst_and_prove_finite
	\|> Local_Theory.raw_theory inst_and_prove_enum
	end

	fun def_types (trac:TracProtocol.protocol) lthy =
	let
	val pname = #name trac
	val defname = mkN(pname, enum_constsN)
	val _ = info(" Defining "^defname)
	val tnames = get_enums trac
	val types = map (fn x => ([],x)) tnames
	in
	([defname], ml_isar_wrapper.define_simple_datatype ([], defname) types lthy)
	end

	fun def_sets (trac:TracProtocol.protocol) lthy =
	let
	val pname = #name trac
	val defname = mkN(pname, setsN)
	val _ = info (" Defining "^defname)

	val sspec = get_set_spec trac
	val tfqn = Local_Theory.full_name lthy (Binding.name (mkN(pname, enum_constsN)))
	val ttyp = Type(tfqn, [])
	val types = map (fn (x,n) => (replicate n ttyp,x)) sspec
	in
	lthy
	\|> ml_isar_wrapper.define_simple_datatype ([], defname) types
	end

	fun def_funs (trac:TracProtocol.protocol) lthy =
	let
	val pname = #name trac
	val (pub_f, pub_c, priv) = get_funs trac
	val pub = pub_f@pub_c

	fun def_atom lthy =
	let
	val def_atomname = mkN(pname, atomN)
	val types =
	if null pub_c
	then types
	else types@[other_pubconsts_typeN]
	fun define_atom_dt lthy =
	let
	val _ = info(" Defining "^def_atomname)
	in
	lthy
	\|> ml_isar_wrapper.define_simple_datatype ([], def_atomname) (map (fn x => ([],x)) types)
	end
	fun prove_UNIV_atom lthy =
	let
	val _ = info (" Proving "^def_atomname^"_UNIV")
	val thmsN = [def_atomname^".exhaust"]
	val fqn = Local_Theory.full_name lthy (Binding.name (mkN(pname, atomN)))
	val typ = Type(fqn, [])
	in
	lthy
	\|> prove_UNIV (def_atomname) typ (map (fn c => Const(fqn^"."^c,typ)) types) thmsN
	end
	in
	lthy
	\|> define_atom_dt
	\|> prove_UNIV_atom
	end

	fun def_fun_dt lthy =
	let
	val def_funname = mkN(pname, funN)
	val _ = info(" Defining "^def_funname)
	val types = map (fn x => ([],x)) (map fst (pub@priv))
	val ctyp = Type(Local_Theory.full_name lthy (Binding.name (mkN(pname, enum_constsN))), [])
	in
	ml_isar_wrapper.define_simple_datatype ([], def_funname) (types@[([ctyp],enumN)]) lthy
	end

	fun def_fun_arity lthy =
	let
	val fqn_name = Local_Theory.full_name lthy (Binding.name (mkN(pname, funN)))
	val ctyp = Type(fqn_name, [])

	fun mk_rec_eq name (fname,arity) = (Free(name,ctyp --> natT)
	$Const(fqn_name^"."^fname,ctyp),
	mk_nat((Option.valOf o Int.fromString) arity))
	val name = mkN(pname, arityN)
	val _ = info(" Defining "^name)
	val ctyp' = Type(Local_Theory.full_name lthy (Binding.name (mkN(pname, enum_constsN))), [])
	in
	ml_isar_wrapper.define_simple_fun name
	((map (mk_rec_eq name) (pub@priv))@[
	(Free(name, ctyp --> natT)
	$(Const(fqn_name^"."^enumN, ctyp' --> ctyp)$(Term.dummy_pattern ctyp')),
	mk_nat(0))]) lthy
	end

	fun def_public lthy =
	let
	val fqn_name = Local_Theory.full_name lthy (Binding.name (mkN(pname, funN)))
	val ctyp = Type(fqn_name, [])

	fun mk_rec_eq name t fname = (Free(name, ctyp --> boolT)
	$Const(fqn_name^"."^fname,ctyp), t)
	val name = mkN(pname, publicN)
	val _ = info(" Defining "^name)
	val ctyp' = Type(Local_Theory.full_name lthy (Binding.name (mkN(pname, enum_constsN))), [])
	in
	ml_isar_wrapper.define_simple_fun name
	((map (mk_rec_eq name (@{term "False"})) (map fst priv))
	@(map (mk_rec_eq name (@{term "True"})) (map fst pub))
	@[(Free(name, ctyp --> boolT)
	$(Const(fqn_name^"."^enumN, ctyp' --> ctyp)$(Term.dummy_pattern ctyp')),
	@{term "True"})]) lthy
	end

	fun def_gamma lthy =
	let
	fun optionT t = Type (@{type_name "option"}, [t])
	fun mk_Some t = Const (@{const_name "Some"}, t --> optionT t)
	fun mk_None t = Const (@{const_name "None"}, optionT t)

	val fqn_name = Local_Theory.full_name lthy (Binding.name (mkN(pname, funN)))
	val ctyp = Type(fqn_name, [])
	val atomFQN = Local_Theory.full_name lthy (Binding.name (mkN(pname, atomN)))
	val atomT = Type(atomFQN, [])

	fun mk_rec_eq name t fname = (Free(name, ctyp --> optionT atomT)
	$Const(fqn_name^"."^fname,ctyp), t)
	val name = mkN(pname, gammaN)
	val _ = info(" Defining "^name)
	val ctyp' = Type(Local_Theory.full_name lthy (Binding.name (mkN(pname, enum_constsN))), [])
	in
	ml_isar_wrapper.define_simple_fun name
	((map (mk_rec_eq name ((mk_Some atomT)$(Const(atomFQN^"."^secret_typeN, atomT)))) (map fst priv))
	@(map (mk_rec_eq name ((mk_Some atomT)$(Const(atomFQN^"."^other_pubconsts_typeN, atomT)))) (map fst pub_c))
	@[(Free(name, ctyp --> optionT atomT)
	$(Const(fqn_name^"."^enumN, ctyp' --> ctyp)$(Term.dummy_pattern ctyp')),
	(mk_Some atomT)$(Const(atomFQN^"."^enum_typeN,atomT)))]
	@(map (mk_rec_eq name (mk_None atomT)) (map fst pub_f)) ) lthy
	end

	fun def_ana lthy = let
	val pname = #name trac
	val (pub_f, pub_c, priv) = get_funs trac
	val pub = pub_f@pub_c

	val keyT = messageT' natT trac lthy

	val fqn_name = Local_Theory.full_name lthy (Binding.name (mkN(pname, funN)))
	val ctyp = Type(fqn_name, [])

	val ana_outputT = mk_prodT (mk_listT keyT, mk_listT natT)

	val default_output = mk_prod (mk_list keyT [], mk_list natT [])

	fun mk_ana_output ks rs = mk_prod (mk_list keyT ks, mk_list natT rs)

	fun mk_rec_eq name t fname = (Free(name, ctyp --> ana_outputT)
	$Term.Const(fqn_name^"."^fname,ctyp), t)
	val name = mkN(pname, anaN)
	val _ = info(" Defining "^name)
	val ctyp' = Type(Local_Theory.full_name lthy (Binding.name (mkN(pname, enum_constsN))), [])

	val ana_spec =
	let
	val toInt = Option.valOf o Int.fromString
	fun ana_arity (f,n) = (if is_priv_fun trac f then (toInt n)-1 else toInt n)
	fun check_valid_arity ((f,ps),ks,rs) =
	case List.find (fn g => f = fst g) pub_f of
	SOME (f',n) =>
	if length ps <> ana_arity (f',n)
	then error ("Invalid number of parameters in the analysis rule for " ^ f ^
	" (expected " ^ Int.toString (ana_arity (f',n)) ^
	" but got " ^ Int.toString (length ps) ^ ")")
	else ((f,ps),ks,rs)
	\| NONE => error (f ^ " is not a declared function symbol of arity greater than zero")
	val transform_cMsg = transform_cMsg trac
	val rm_special_funs = rm_special_funs (fn ((f,_),_,_) => f)
	fun var_to_nat f xs x =
	let
	val n = snd (Option.valOf ((list_find (fn y => y = x) xs)))
	in
	if is_priv_fun trac f then mk_nat (1+n) else mk_nat n
	end
	fun c_to_h f xs t = ana_cMsg_to_hol (is_priv_fun trac f) t xs trac lthy
	fun keys f ps ks = map (c_to_h f ps o transform_cMsg o Trac_Term.certifyMsg [] []) ks
	fun results f ps rs = map (var_to_nat f ps) rs
	fun aux ((f,ps),ks,rs) = (f, mk_ana_output (keys f ps ks) (results f ps rs))
	in
	map (aux o check_valid_arity) (rm_special_funs (#analysis_spec trac))
	end

	val other_funs =
	filter (fn f => not (List.exists (fn g => f = g) (map fst ana_spec))) (map fst (pub@priv))
	in
	ml_isar_wrapper.define_simple_fun name
	((map (fn (f,out) => mk_rec_eq name out f) ana_spec)
	@(map (mk_rec_eq name default_output) other_funs)
	@[(Free(name, ctyp --> ana_outputT)
	$(Term.Const(fqn_name^"."^enumN, ctyp' --> ctyp)$(Term.dummy_pattern ctyp')),
	default_output)]) lthy
	end

	in
	lthy \|> def_atom
	\|> def_fun_dt
	\|> def_fun_arity
	\|> def_public
	\|> def_gamma
	\|> def_ana
	end

	fun define_term_model (trac:TracProtocol.protocol) lthy =
	let
	val _ = info("Defining term model")
	in
	lthy \|> snd o def_types trac
	\|> def_sets trac
	\|> def_funs trac
	end

	fun define_fixpoint fp trac print lthy =
	let
	val fp_name = mkN (#name trac, "fixpoint")
	val _ = info("Defining fixpoint")
	val _ = info(" Defining "^fp_name)
	val fp_triple = transform_fp trac fp
	val fp_triple_trm = fp_triple_to_hol fp_triple trac lthy
	val trac = TracProtocol.update_fixed_point trac (SOME fp_triple)
	in
	(trac, #2 (ml_isar_wrapper.define_constant_definition' (fp_name, fp_triple_trm) print lthy))
	end

	fun define_protocol print ((trac:TracProtocol.protocol), lthy) = let
	val _ =
	if length (#transaction_spec trac) > 1
	then info("Defining protocols")
	else info("Defining protocol")
	val pname = #name trac

	val flat_type_spec = flatten_type_spec trac

	val mk_Transaction = mk_Transaction trac lthy

	val mk_Send = mk_Send_step trac lthy
	val mk_Receive = mk_Receive_step trac lthy
	val mk_InSet = mk_InSet_step trac lthy
	val mk_NotInSet = mk_NotInSet_step trac lthy
	val mk_Inequality = mk_Inequality_step trac lthy
	val mk_Insert = mk_Insert_step trac lthy
	val mk_Delete = mk_Delete_step trac lthy

	val star_label = mk_star_label
	val prot_label = mk_prot_label

	val certify_transation = TracProtocol.certifyTransaction

	fun mk_tname i (tr:TracProtocol.transaction_name) =
	let
	val x = #1 tr
	val y = case i of NONE => x \| SOME n => mkN(n, x)
	val z = mkN("transaction", y)
	in mkN(pname, z)
	end

	fun def_transaction name_prefix prot_num (transaction:TracProtocol.cTransaction) lthy = let
	val defname = mk_tname name_prefix (#transaction transaction)
	val _ = info(" Defining "^defname)

	val receives = #receive_actions transaction
	val checkssingle = #checksingle_actions transaction
	val checksall = #checkall_actions transaction
	val updates = #update_actions transaction
	val sends = #send_actions transaction
	val fresh = get_fresh_value_variables transaction
	val attack_signals = #attack_actions transaction

	val nonfresh_value_vars = get_nonfresh_value_variables transaction
	val value_vars = get_value_variables transaction
	val enum_vars = get_enum_variables transaction

	val (enum_ineqs, value_ineqs) = get_variable_restrictions transaction

	val transform_cMsg = transform_cMsg trac

	fun c_to_h trm = transaction_cMsg_to_hol (transform_cMsg trm) prot_num value_vars trac lthy

	val abstract_over_enum_vars = fn x => fn y => fn z =>
	abstract_over_enum_vars x y z flat_type_spec trac lthy

	fun mk_transaction_term (rcvs, chcksingle, chckall, upds, snds, frsh, atcks) =
	let
	open Trac_Term
	fun action_filter f (lbl,a) = case f a of SOME x => SOME (lbl,x) \| NONE => NONE

	fun lbl_to_h (TracProtocol.LabelS) = star_label
	\| lbl_to_h (TracProtocol.LabelN) = prot_label prot_num

	fun lbl_trm_to_h f (lbl,t) = f (lbl_to_h lbl) (c_to_h t)

	val S1 = map (lbl_trm_to_h mk_Receive)
	(map_filter (action_filter TracProtocol.maybe_the_Receive) rcvs)

	val S2 =
	let
	fun aux (lbl,TracProtocol.cInequality (x,y)) =
	SOME (mk_Inequality (lbl_to_h lbl) (c_to_h x) (c_to_h y))
	\| aux (lbl,TracProtocol.cInSet (e,s)) =
	SOME (mk_InSet (lbl_to_h lbl) (c_to_h e) (c_to_h s))
	\| aux (lbl,TracProtocol.cNotInSet (e,s)) =
	SOME (mk_NotInSet (lbl_to_h lbl) (c_to_h e) (c_to_h s))
	\| aux _ = NONE
	in
	map_filter aux chcksingle
	end

	val S3 =
	let
	fun arity s = case set_arity trac s of
	SOME n => n
	\| NONE => error ("Not a set family: " ^ s)

	fun mk_evs s = map (fn n => ("X" ^ Int.toString n, "")) (0 upto ((arity s) -1))

	fun mk_trm (lbl,e,s) =
	let
	val ps = map (fn x => cVar (x,Untyped)) (map fst (mk_evs s))
	in
	mk_NotInSet (lbl_to_h lbl) (c_to_h e) (c_to_h (cSet (s,ps)))
	end

	fun mk_trms (lbl,(e,s)) =
	abstract_over_enum_vars (mk_evs s) [] (mk_trm (lbl,e,s))
	in
	map mk_trms (map_filter (action_filter TracProtocol.maybe_the_NotInAny) chckall)
	end

	val S4 = map (c_to_h o mk_Value_cVar) frsh

	val S5 =
	let
	fun aux (lbl,TracProtocol.cInsert (e,s)) =
	SOME (mk_Insert (lbl_to_h lbl) (c_to_h e) (c_to_h s))
	\| aux (lbl,TracProtocol.cDelete (e,s)) =
	SOME (mk_Delete (lbl_to_h lbl) (c_to_h e) (c_to_h s))
	\| aux _ = NONE
	in
	map_filter aux upds
	end

	val S6 =
	let val snds' = map_filter (action_filter TracProtocol.maybe_the_Send) snds
	in map (lbl_trm_to_h mk_Send) (snds'@map (fn (lbl,_) => (lbl,cAttack)) atcks) end
	in
	abstract_over_enum_vars enum_vars enum_ineqs (mk_Transaction S1 S2 S3 S4 S5 S6)
	end

	fun def_trm trm print lthy =
	#2 (ml_isar_wrapper.define_constant_definition' (defname, trm) print lthy)

	val additional_value_ineqs =
	let
	open Trac_Term
	open TracProtocol
	val poschecks = map_filter (maybe_the_InSet o snd) checkssingle
	val negchecks_single = map_filter (maybe_the_NotInSet o snd) checkssingle
	val negchecks_all = map_filter (maybe_the_NotInAny o snd) checksall

	fun aux' (cVar (x,ValueType),s) (cVar (y,ValueType),t) =
	if s = t then SOME (x,y) else NONE
	\| aux' _ _ = NONE

	fun aux (x,cSet (s,ps)) = SOME (
	map_filter (aux' (x,cSet (s,ps))) negchecks_single@
	map_filter (aux' (x,s)) negchecks_all
	)
	\| aux _ = NONE
	in
	List.concat (map_filter aux poschecks)
	end

	val all_value_ineqs = mk_unique (value_ineqs@additional_value_ineqs)

	val valvarsprod =
	filter (fn p => not (List.exists (fn q => p = q orelse swap p = q) all_value_ineqs))
	(list_triangle_product (fn x => fn y => (x,y)) nonfresh_value_vars)

	val transaction_trm0 = mk_transaction_term
	(receives, checkssingle, checksall, updates, sends, fresh, attack_signals)
	in
	if null valvarsprod
	then def_trm transaction_trm0 print lthy
	else let
	val partitions = list_partitions nonfresh_value_vars all_value_ineqs
	val ps = filter (not o null) (map (filter (fn x => length x > 1)) partitions)

	fun mk_subst ps =
	let
	open Trac_Term
	fun aux [] = NONE
	\| aux (x::xs) = SOME (map (fn y => (y,cVar (x,ValueType))) xs)
	in
	List.concat (map_filter aux ps)
	end

	fun apply d =
	let
	val ap = TracProtocol.subst_apply_actions d
	fun f (TracProtocol.cInequality (x,y)) = x <> y
	\| f _ = true
	val checksingle' = filter (f o snd) (ap checkssingle)
	in
	(ap receives, checksingle', ap checksall, ap updates, ap sends, fresh, attack_signals)
	end

	val transaction_trms = transaction_trm0::map (mk_transaction_term o apply o mk_subst) ps
	val transaction_typ = Term.fastype_of transaction_trm0

	fun mk_concat_trm tau trms =
	Term.Const (@{const_name "concat"}, mk_listT tau --> tau) $ mk_list tau trms
	in
	def_trm (mk_concat_trm transaction_typ transaction_trms) print lthy
	end
	end

	val def_transactions =
	let
	val prots = map (fn (n,pr) => map (fn tr => (n,tr)) pr) (#transaction_spec trac)
	val lbls = list_upto (length prots)
	val lbl_prots = List.concat (map (fn i => map (fn tr => (i,tr)) (nth prots i)) lbls)
	val f = fold (fn (i,(n,tr)) => def_transaction n i (certify_transation tr))
	in
	f lbl_prots
	end

	fun def_protocols lthy = let
	fun mk_prot_def (name,trm) lthy =
	let val _ = info(" Defining "^name)
	in #2 (ml_isar_wrapper.define_constant_definition' (name,trm) print lthy)
	end

	val prots = #transaction_spec trac
	val num_prots = length prots

	val pdefname = mkN(pname, "protocol")

	fun mk_tnames i =
	let
	val trs = case nth prots i of (j,prot) => map (fn tr => (j,tr)) prot
	in map (fn (j,s) => full_name (mk_tname j (#transaction s)) lthy) trs
	end

	val tnames = List.concat (map mk_tnames (list_upto num_prots))

	val pnames =
	let
	val f = fn i => (Int.toString i,nth prots i)
	val g = fn (i,(n,_)) => case n of NONE => i \| SOME m => m
	val h = fn s => mkN (pdefname,s)
	in map (h o g o f) (list_upto num_prots)
	end

	val trtyp = prot_transactionT trac lthy
	val trstyp = mk_listT trtyp

	fun mk_prot_trm names =
	Term.Const (@{const_name "concat"}, mk_listT trstyp --> trstyp) $
	mk_list trstyp (map (fn x => Term.Const (x, trstyp)) names)

	val lthy =
	if num_prots > 1
	then fold (fn (i,pname) => mk_prot_def (pname, mk_prot_trm (mk_tnames i)))
	(map (fn i => (i, nth pnames i)) (list_upto num_prots))
	lthy
	else lthy

	val pnames' = map (fn n => full_name n lthy) pnames

	fun mk_prot_trm_with_star i =
	let
	fun f j =
	if j = i
	then Term.Const (nth pnames' j, trstyp)
	else (Term.Const (@{const_name "map"}, [trtyp --> trtyp, trstyp] ---> trstyp) $
	Term.Const ("Transactions.transaction_star_proj", trtyp --> trtyp) $
	Term.Const (nth pnames' j, trstyp))
	in
	Term.Const (@{const_name "concat"}, mk_listT trstyp --> trstyp) $
	mk_list trstyp (map f (list_upto num_prots))
	end

	val lthy =
	if num_prots > 1
	then fold (fn (i,pname) => mk_prot_def (pname, mk_prot_trm_with_star i))
	(map (fn i => (i, nth pnames i ^ "_with_star")) (list_upto num_prots))
	lthy
	else lthy
	in
	mk_prot_def (pdefname, mk_prot_trm (if num_prots > 1 then pnames' else tnames)) lthy
	end
	in
	(trac, lthy \|> def_transactions \|> def_protocols)
	end
	end
	\<close>

	ML\<open>
	structure trac = struct
	open Trac_Term

	val info = Output.information
	(* Define global configuration option "trac" *)
	(* val trac_fp_compute_binary_cfg =
	let
	val (trac_fp_compute_path_config, trac_fp_compute_path_setup) =
	Attrib.config_string (Binding.name "trac_fp_compute") (K "trac_fp_compute")
	in
	Context.>>(Context.map_theory trac_fp_compute_path_setup);
	trac_fp_compute_path_config
	end

	val trac_eval_cfg =
	let
	val (trac_fp_compute_eval_config, trac_fp_compute_eval) =
	Attrib.config_bool (Binding.name "trac_fp_compute_eval") (K false)
	in
	Context.>>(Context.map_theory trac_fp_compute_eval);
	trac_fp_compute_eval_config
	end *)

	type hide_tvar_tab = (TracProtocol.protocol) Symtab.table
	fun trac_eq (a, a') = (#name a) = (#name a')
	fun merge_trac_tab (tab,tab') = Symtab.merge trac_eq (tab,tab')
	structure Data = Generic_Data
	(
	type T = hide_tvar_tab
	val empty = Symtab.empty:hide_tvar_tab
	fun merge(t1,t2) = merge_trac_tab (t1, t2)
	);

	fun update p thy = Context.theory_of
	((Data.map (fn tab => Symtab.update (#name p, p) tab) (Context.Theory thy)))
	fun lookup name thy = (Symtab.lookup ((Data.get o Context.Theory) thy) name,thy)

	fun mk_abs_filename thy filename =
	let
	val filename = Path.explode filename
	val master_dir = Resources.master_directory thy
	in
	Path.implode (if (Path.is_absolute filename)
	then filename
	else master_dir + filename)
	end

	(* fun exec {trac_path, error_detail} filename = let
	open OS.FileSys OS.Process

	val tmpname = tmpName()
	val err_tmpname = tmpName()
	fun plural 1 = "" \| plural _ = "s"
	val trac = case trac_path of
	SOME s => s
	\| NONE => raise error ("trac_fp_compute_path not specified")
	val cmdline = trac ^ " \"" ^ filename ^ "\" > " ^ tmpname ^ " 2> " ^ err_tmpname
	in
	if isSuccess (system cmdline) then (OS.FileSys.remove err_tmpname; tmpname)
	else let val _ = OS.FileSys.remove tmpname
	val (msg, rest) = File.read_lines (Path.explode err_tmpname) \|> chop error_detail
	val _ = OS.FileSys.remove err_tmpname
	val _ = warning ("trac failed on " ^ filename ^ "\nCommand: " ^ cmdline ^
	"\n\nOutput:\n" ^
	cat_lines (msg @ (if null rest then [] else
	["(... " ^ string_of_int (length rest) ^
	" more line" ^ plural (length rest) ^ ")"])))
	in raise error ("trac failed on " ^ filename) end
	end *)

	fun lookup_trac (pname:string) lthy =
	Option.valOf (fst (lookup pname (Proof_Context.theory_of lthy)))

	fun def_fp fp_str print (trac, lthy) =
	let
	val fp = TracFpParser.parse_str fp_str
	val (trac,lthy) = trac_definitorial_package.define_fixpoint fp trac print lthy
	val lthy = Local_Theory.raw_theory (update trac) lthy
	in
	(trac, lthy)
	end

	fun def_fp_file filename print (trac, lthy) = let
	val thy = Proof_Context.theory_of lthy
	val abs_filename = mk_abs_filename thy filename
	val fp = TracFpParser.parse_file abs_filename
	val (trac,lthy) = trac_definitorial_package.define_fixpoint fp trac print lthy
	val lthy = Local_Theory.raw_theory (update trac) lthy
	in
	(trac, lthy)
	end

	fun def_fp_trac fp_filename print (trac, lthy) = let
	open OS.FileSys OS.Process
	val _ = info("Checking protocol specification with trac.")
	val thy = Proof_Context.theory_of lthy
	(* val trac = Config.get_global thy trac_binary_cfg *)
	val abs_filename = mk_abs_filename thy fp_filename
	(* val fp_file = exec {error_detail=10, trac_path = SOME trac} abs_filename *)
	(* val fp_raw = File.read (Path.explode fp_file) *)
	val fp_raw = File.read (Path.explode abs_filename)
	val fp = TracFpParser.parse_str fp_raw
	(* val _ = OS.FileSys.remove fp_file *)
	val _ = if TracFpParser.attack fp
	then
	error (" ATTACK found, skipping generating of Isabelle/HOL definitions.\n\n")
	else
	info(" No attack found, continue with generating Isabelle/HOL definitions.")
	val (trac,lthy) = trac_definitorial_package.define_fixpoint fp trac print lthy
	val lthy = Local_Theory.raw_theory (update trac) lthy
	in
	(trac, lthy)
	end

	fun def_trac_term_model str lthy = let
	val trac = TracProtocolParser.parse_str str
	val lthy = Local_Theory.raw_theory (update trac) lthy
	val lthy = trac_definitorial_package.define_term_model trac lthy
	in
	(trac, lthy)
	end

	val def_trac_protocol = trac_definitorial_package.define_protocol

	fun def_trac str print = def_trac_protocol print o def_trac_term_model str

	fun def_trac_file filename print lthy = let
	val trac_raw = File.read (Path.explode filename)
	val (trac,lthy) = def_trac trac_raw print lthy
	val lthy = Local_Theory.raw_theory (update trac) lthy
	in
	(trac, lthy)
	end

	fun def_trac_fp_trac trac_str print lthy = let
	open OS.FileSys OS.Process
	val (trac,lthy) = def_trac trac_str print lthy
	val tmpname = tmpName()
	val _ = File.write (Path.explode tmpname) trac_str
	val (trac,lthy) = def_fp_trac tmpname print (trac, lthy)
	val _ = OS.FileSys.remove tmpname
	val lthy = Local_Theory.raw_theory (update trac) lthy
	in
	lthy
	end

	end
	\<close>

	ML\<open>
	val fileNameP = Parse.name -- Parse.name

	val _ = Outer_Syntax.local_theory' @{command_keyword "trac_import"}
	"Import protocol and fixpoint from trac files."
	(fileNameP >> (fn (trac_filename, fp_filename) => fn print =>
	trac.def_trac_file trac_filename print #>
	trac.def_fp_file fp_filename print #> snd));

	val _ = Outer_Syntax.local_theory' @{command_keyword "trac_import_trac"}
	"Import protocol from trac file and compute fixpoint with trac."
	(fileNameP >> (fn (trac_filename, fp_filename) => fn print =>
	trac.def_trac trac_filename print #> trac.def_fp_trac fp_filename print #> snd));

	val _ = Outer_Syntax.local_theory' @{command_keyword "trac_trac"}
	"Define protocol using trac format and compute fixpoint with trac."
	(Parse.cartouche >> (fn trac => fn print => trac.def_trac_fp_trac trac print));

	val _ = Outer_Syntax.local_theory' @{command_keyword "trac"}
	"Define protocol and (optionally) fixpoint using trac format."
	(Parse.cartouche -- Scan.optional Parse.cartouche "" >> (fn (trac,fp) => fn print =>
	if fp = ""
	then trac.def_trac trac print #> snd
	else trac.def_trac trac print #> trac.def_fp fp print #> snd));
	\<close>

	ML\<open>
	val name_prefix_parser = Parse.!!! (Parse.name --\| Parse.$$$ ":" -- Parse.name)

	(* Original definition (opt_evaluator) copied from value_command.ml *)
	val opt_proof_method_choice =
	Scan.optional (\<^keyword>\<open>[\<close> \|-- Parse.name --\| \<^keyword>\<open>]\<close>) "safe";

	(* Original definition (locale_expression) copied from parse_spec.ML *)
	val opt_defs_list = Scan.optional
	(\<^keyword>\<open>for\<close> \|-- Scan.repeat1 Parse.name >>
	(fn xs => if length xs > 3 then error "Too many optional arguments" else xs))
	[];

	val security_proof_locale_parser =
	name_prefix_parser -- opt_defs_list

	val security_proof_locale_parser_with_method_choice =
	opt_proof_method_choice -- name_prefix_parser -- opt_defs_list


	fun protocol_model_setup_proof_state name prefix lthy =
	let
	fun f x y z = ([((x,Position.none),((y,true),(Expression.Positional z,[])))],[])
	val _ = if name = "" then error "No name given" else ()
	val pexpr = f "stateful_protocol_model" name (protocol_model_interpretation_params prefix)
	val pdefs = protocol_model_interpretation_defs name
	val proof_state = Interpretation.global_interpretation_cmd pexpr pdefs lthy
	in
	proof_state
	end

	fun protocol_security_proof_proof_state manual_proof name prefix opt_defs print lthy =
	let
	fun f x y z = ([((x,Position.none),((y,true),(Expression.Positional z,[])))],[])
	val _ = if name = "" then error "No name given" else ()
	val num_defs = length opt_defs
	val pparams = protocol_model_interpretation_params prefix
	val default_defs = [prefix ^ "_" ^ "protocol", prefix ^ "_" ^ "fixpoint"]
	fun g locale_name extra_params = f locale_name name (pparams@map SOME extra_params)
	val (prot_fp_smp_names, pexpr) = if manual_proof
	then (case num_defs of
	0 => (default_defs, g "secure_stateful_protocol'" default_defs)
	\| 1 => (opt_defs, g "secure_stateful_protocol''" opt_defs)
	\| 2 => (opt_defs, g "secure_stateful_protocol'" opt_defs)
	\| _ => (opt_defs, g "secure_stateful_protocol" opt_defs))
	else (case num_defs of
	0 => (default_defs, g "secure_stateful_protocol''''" default_defs)
	\| 1 => (opt_defs, g "secure_stateful_protocol''" opt_defs)
	\| 2 => (opt_defs, g "secure_stateful_protocol''''" opt_defs)
	\| _ => (opt_defs, g "secure_stateful_protocol'''" opt_defs))
	val proof_state = lthy \|> declare_protocol_checks print
	\|> Interpretation.global_interpretation_cmd pexpr []
	in
	(prot_fp_smp_names, proof_state)
	end

	val _ =
	Outer_Syntax.local_theory \<^command_keyword>\<open>protocol_model_setup\<close>
	"prove interpretation of protocol model locale into global theory"
	(name_prefix_parser >> (fn (name,prefix) => fn lthy =>
	let
	val proof_state = protocol_model_setup_proof_state name prefix lthy
	val meth =
	let
	val m = "protocol_model_interpretation"
	val _ = Output.information (
	"Proving protocol model locale instance with proof method " ^ m)
	in
	Method.Source (Token.make_src (m, Position.none) [])
	end
	in
	ml_isar_wrapper.prove_state_simple meth proof_state
	end));

	val _ =
	Outer_Syntax.local_theory_to_proof \<^command_keyword>\<open>manual_protocol_model_setup\<close>
	"prove interpretation of protocol model locale into global theory"
	(name_prefix_parser >> (fn (name,prefix) => fn lthy =>
	let
	val proof_state = protocol_model_setup_proof_state name prefix lthy
	val subgoal_proof = " subgoal by protocol_model_subgoal\n"
	val _ = Output.information ("Example proof:\n" ^
	Active.sendback_markup_command (" apply unfold_locales\n"^
	subgoal_proof^
	subgoal_proof^
	subgoal_proof^
	subgoal_proof^
	subgoal_proof^
	" done\n"))
	in
	proof_state
	end));

	val _ =
	Outer_Syntax.local_theory' \<^command_keyword>\<open>protocol_security_proof\<close>
	"prove interpretation of secure protocol locale into global theory"
	(security_proof_locale_parser_with_method_choice >> (fn params => fn print => fn lthy =>
	let
	val ((opt_meth_level,(name,prefix)),opt_defs) = params
	val (defs, proof_state) =
	protocol_security_proof_proof_state false name prefix opt_defs print lthy
	val num_defs = length defs
	val meth =
	let
	val m = case opt_meth_level of
	"safe" => "check_protocol" ^ "'" (* (if num_defs = 1 then "'" else "") *)
	\| "unsafe" => "check_protocol_unsafe" ^ "'" (* (if num_defs = 1 then "'" else "") *)
	\| _ => error ("Invalid option: " ^ opt_meth_level)
	val _ = Output.information (
	"Proving security of protocol " ^ nth defs 0 ^ " with proof method " ^ m)
	val _ = if num_defs > 1 then Output.information ("Using fixpoint " ^ nth defs 1) else ()
	val _ = if num_defs > 2 then Output.information ("Using SMP set " ^ nth defs 2) else ()
	in
	Method.Source (Token.make_src (m, Position.none) [])
	end
	in
	ml_isar_wrapper.prove_state_simple meth proof_state
	end
	));

	val _ =
	Outer_Syntax.local_theory_to_proof' \<^command_keyword>\<open>manual_protocol_security_proof\<close>
	"prove interpretation of secure protocol locale into global theory"
	(security_proof_locale_parser >> (fn params => fn print => fn lthy =>
	let
	val ((name,prefix),opt_defs) = params
	val (defs, proof_state) =
	protocol_security_proof_proof_state true name prefix opt_defs print lthy
	val subgoal_proof =
	let
	val m = "code_simp" (* case opt_meth_level of
	"safe" => "code_simp"
	\| "unsafe" => "eval"
	\| _ => error ("Invalid option: " ^ opt_meth_level) *)
	in
	" subgoal by " ^ m ^ "\n"
	end
	val _ = Output.information ("Example proof:\n" ^
	Active.sendback_markup_command (" apply check_protocol_intro\n"^
	subgoal_proof^
	(if length defs = 1 then ""
	else subgoal_proof^
	subgoal_proof^
	subgoal_proof^
	subgoal_proof)^
	" done\n"))
	in
	proof_state
	end
	));
	\<close>

	end