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OCaml_program_corpus

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let preserve ( ? rev_namespace = [ ] ) ocaml = translate ~ rev_namespace ~ ocaml ~ coq : ocaml
let rec find ( ? rev_namespace = [ ] ) ~ ocaml t = let prefix = String . concat " . " rev_namespace in match Option . bind ( Table . find_opt prefix t ) ( Namespace . find ~ ocaml ) with \| Some coq -> Some coq \| None -> ( match rev_namespace with \| _ :: rev_namespace -> find ~ rev_namespace ~ ocaml t \| _ -> None )
let types_table = let rec ( -- ) x y = if x < y then x :: ( x + 1 -- y ) else [ y ] in let translate_tuples l ns = List . fold_left ( fun ns x -> Namespace . translate ~ ocaml ( : Format . sprintf " Coq_coqffi . Shim . tupl % d " x ) ~ coq ( : Format . sprintf " tupl % d " x ) ns ) ns l in let ns = Namespace . empty \|> Namespace . preserve " bool " \|> Namespace . translate ~ ocaml " : char " ~ coq " : ascii " \|> Namespace . translate ~ ocaml " : int " ~ coq " : i63 " \|> Namespace . translate ~ ocaml " : Stdlib . Seq . t " ~ coq " : Seq . t " \|> Namespace . translate ~ ocaml " : Stdlib . result " ~ coq " : sum " \|> Namespace . translate ~ ocaml " : int32 " ~ coq " : i32 " \|> translate_tuples ( 3 -- max_tuple_size ) \|> Namespace . preserve " float " \|> Namespace . preserve " list " \|> Namespace . preserve " option " \|> Namespace . preserve " string " \|> Namespace . preserve " unit " \|> Namespace . preserve " exn " in Table . add " " ns empty
type token = \| Range of Ckappa_sig . c_site_name * Ckappa_sig . c_state list \| Equiv of ( Ckappa_sig . c_site_name * Ckappa_sig . c_state ) * ( Ckappa_sig . c_site_name * Ckappa_sig . c_state ) \| Imply of ( Ckappa_sig . c_site_name * Ckappa_sig . c_state ) * ( Ckappa_sig . c_site_name * Ckappa_sig . c_state ) \| Partition of ( Ckappa_sig . c_site_name * ( Ckappa_sig . c_state * token list ) list ) \| No_known_translation of ( Ckappa_sig . c_site_name * Ckappa_sig . c_state ) list list
type rename_sites = ( Remanent_parameters_sig . parameters -> Exception . method_handler -> Ckappa_sig . Site_map_and_set . Map . elt -> Exception . method_handler * Ckappa_sig . Site_map_and_set . Map . elt )
let non_relational parameters handler error mvbdu = let error , handler , list = Ckappa_sig . Views_bdu . mvbdu_cartesian_abstraction parameters handler error mvbdu in let error , handler , mvbdu_true = Ckappa_sig . Views_bdu . mvbdu_true parameters handler error in let error , handler , recomposition = List . fold_left ( fun ( error , handler , conjunct ) term -> Ckappa_sig . Views_bdu . mvbdu_and parameters handler error conjunct term ) ( error , handler , mvbdu_true ) list in error , handler , Ckappa_sig . Views_bdu . equal mvbdu recomposition
let try_partitioning parameters handler error ( rename_site_inverse : rename_sites ) mvbdu = let error , handler , mvbdu_true = Ckappa_sig . Views_bdu . mvbdu_true parameters handler error in let error , handler , var_hconsed_list = Ckappa_sig . Views_bdu . variables_list_of_mvbdu parameters handler error mvbdu in let error , handler , var_list = Ckappa_sig . Views_bdu . extensional_of_variables_list parameters handler error var_hconsed_list in let rec aux l ( error , handler ) = match l with \| [ ] -> error , handler , None \| head :: tail -> let error ' , handler , singleton = Ckappa_sig . Views_bdu . build_variables_list parameters handler error [ head ] in let error = Exception . check_point Exception . warn parameters error error ' __POS__ Exit in let error_2 , handler , mvbdu_ref = Ckappa_sig . Views_bdu . mvbdu_project_abstract_away parameters handler error mvbdu singleton in let error = Exception . check_point Exception . warn parameters error error_2 __POS__ Exit in let error_3 , handler , proj_in = Ckappa_sig . Views_bdu . mvbdu_project_keep_only parameters handler error mvbdu singleton in let error = Exception . check_point Exception . warn parameters error error_3 __POS__ Exit in let error_4 , handler , list_asso = Ckappa_sig . Views_bdu . extensional_of_mvbdu parameters handler error proj_in in let error = Exception . check_point Exception . warn parameters error error_4 __POS__ Exit in let error_5 , range = let rec aux2 list ( error , output ) = match list with \| [ ] -> ( error , output ) \| [ ( x , i ) ] :: tail when x = head -> aux2 tail ( error , ( i :: output ) ) \| _ :: tail -> aux2 tail ( Exception . warn parameters error __POS__ Exit output ) in aux2 list_asso ( error , [ ] ) in let error = Exception . check_point Exception . warn parameters error error_5 __POS__ Exit in let rec aux3 list ( error , handler , output ) = match list with \| [ ] -> error , handler , Some output \| h :: t -> begin let error_6 , handler , select = Ckappa_sig . Views_bdu . build_association_list parameters handler error [ head , h ] in let error = Exception . check_point Exception . warn parameters error error_6 __POS__ Exit in let error_7 , handler , mvbdu_case = Ckappa_sig . Views_bdu . mvbdu_redefine parameters handler error mvbdu_true select in let error = Exception . check_point Exception . warn parameters error error_7 __POS__ Exit in let error_8 , handler , case = Ckappa_sig . Views_bdu . mvbdu_and parameters handler error mvbdu_case mvbdu in let error = Exception . check_point Exception . warn parameters error error_8 __POS__ Exit in let error_9 , handler , bool = non_relational parameters handler error case in let error = Exception . check_point Exception . warn parameters error error_9 __POS__ Exit in if bool then let error_10 , handler , away = Ckappa_sig . Views_bdu . mvbdu_project_abstract_away parameters handler error case singleton in let error = Exception . check_point Exception . warn parameters error error_10 __POS__ Exit in if Ckappa_sig . Views_bdu . equal away mvbdu_ref then aux3 t ( error , handler , output ) else let error_11 , handler , list = Ckappa_sig . Views_bdu . mvbdu_cartesian_abstraction parameters handler error away in let error = Exception . check_point Exception . warn parameters error error_11 __POS__ Exit in let error , handler , list = List . fold_left ( fun ( error , handler , list ) elt -> let error , handler , mvbdu_test = Ckappa_sig . Views_bdu . mvbdu_and parameters handler error mvbdu_ref elt in if Ckappa_sig . Views_bdu . equal mvbdu_test mvbdu_ref then error , handler , list else let error_12 , handler , elt = Ckappa_sig . Views_bdu . extensional_of_mvbdu parameters handler error elt in let error = Exception . check_point Exception . warn parameters error error_12 __POS__ Exit in begin let error , var_list_opt = match elt with \| [ ] \| [ ] :: _ \| ( ( _ , _ ) :: _ :: _ ) :: _ -> error , None \| [ ( a , b ) ] :: q -> begin let rec aux4 q output = match q with \| [ ] -> error , Some ( a , output ) \| [ ( c , d ) ] :: q when c = a -> aux4 q ( d :: output ) \| _ -> error , None in aux4 q [ b ] end in match var_list_opt with \| None -> let error , ( ) = Exception . warn parameters error __POS__ Exit ( ) in error , handler , list \| Some ( a , l ) -> let error ' , a ' = rename_site_inverse parameters error a in let error = Exception . check_point Exception . warn parameters error error ' __POS__ Exit in ( error , handler , ( ( Range ( a ' , l ) ) :: list ) ) end ) ( error , handler , [ ] ) ( List . rev list ) in aux3 t ( error , handler , ( ( h , list ) :: output ) ) else error , handler , None end in let error_13 , handler , output = aux3 range ( error , handler , [ ] ) in let error = Exception . check_point Exception . warn parameters error error_13 __POS__ Exit in match output with \| None -> aux tail ( error , handler ) \| Some l -> let error_14 , head = rename_site_inverse parameters error head in let error = Exception . check_point Exception . warn parameters error error_14 __POS__ Exit in error , handler , Some ( head , l ) in aux var_list ( error , handler )
let translate parameters handler error ( rename_site_inverse : rename_sites ) mvbdu = let error , handler , list = Ckappa_sig . Views_bdu . extensional_of_mvbdu parameters handler error mvbdu in let error , list = List . fold_left ( fun ( error , list ) elt1 -> let error , elt1 = List . fold_left ( fun ( error , list ) ( elt2 , asso ) -> let error , elt2 = rename_site_inverse parameters error elt2 in error , ( elt2 , asso ) :: list ) ( error , [ ] ) ( List . rev elt1 ) in error , elt1 :: list ) ( error , [ ] ) ( List . rev list ) in if Remanent_parameters . get_post_processing parameters then begin let error , handler , vars = Ckappa_sig . Views_bdu . variables_list_of_mvbdu parameters handler error mvbdu in let error , handler , var_list = Ckappa_sig . Views_bdu . extensional_of_variables_list parameters handler error vars in let error , var_list = List . fold_left ( fun ( error , list ) elt -> let error , elt = rename_site_inverse parameters error elt in error , elt :: list ) ( error , [ ] ) ( List . rev var_list ) in match var_list with \| [ ] -> error , ( handler , No_known_translation list ) \| [ x ] -> let error , list = List . fold_left ( fun ( error , list ) elt -> match elt with \| [ a , b ] when a = x -> error , b :: list \| _ -> Exception . warn parameters error __POS__ Exit list ) ( error , [ ] ) list in error , ( handler , Range ( x , list ) ) \| [ _ ; _ ] -> begin match list with \| [ ] \| [ _ ] -> Exception . warn parameters error __POS__ Exit ( handler , No_known_translation list ) \| [ [ site1 , state1 ; site2 , state2 ] ; [ site1 ' , state1 ' ; site2 ' , state2 ' ] ] -> begin if site1 = site1 ' && site2 = site2 ' then if state1 > state1 ' then error , ( handler , Equiv ( ( site1 , state1 ) , ( site2 , state2 ) ) ) else error , ( handler , Equiv ( ( site1 , state1 ' ) , ( site2 , state2 ' ) ) ) else Exception . warn parameters error __POS__ Exit ( handler , No_known_translation list ) end \| [ [ site1 , state1 ; site2 , state2 ] ; [ site1 ' , state1 ' ; site2 ' , state2 ' ] ; [ site1 ' ' , state1 ' ' ; site2 ' ' , state2 ' ' ] ] -> begin if site1 = site1 ' && site1 = site1 ' ' && site2 = site2 ' && site2 = site2 ' ' then if state1 = state1 ' then if state1 < state1 ' ' then error , ( handler , Imply ( ( site1 , state1 ' ' ) , ( site2 , state2 ' ' ) ) ) else error , ( handler , Imply ( ( site2 , if state2 = state2 ' ' then state2 ' else state2 ) , ( ( site1 , state1 ) ) ) ) else if state1 = state1 ' ' then if state1 < state1 ' then error , ( handler , Imply ( ( site1 , state1 ' ) , ( site2 , state2 ' ) ) ) else error , ( handler , Imply ( ( site2 , if state2 = state2 ' then state2 ' ' else state2 ) , ( site1 , state1 ) ) ) else if state1 ' = state1 ' ' then if state1 ' < state1 then error , ( handler , Imply ( ( site1 , state1 ) , ( site2 , state2 ) ) ) else error , ( handler , Imply ( ( site2 , if state2 = state2 ' ' then state2 ' else state2 ' ' ) , ( site1 , state1 ' ) ) ) else error , ( handler , No_known_translation list ) else Exception . warn parameters error __POS__ Exit ( handler , No_known_translation list ) end \| _ -> begin let error , handler , output = try_partitioning parameters handler error rename_site_inverse mvbdu in match output with \| None -> error , ( handler , No_known_translation list ) \| Some ( var , l ) -> error , ( handler , Partition ( var , l ) ) end end \| _ -> begin let error , handler , output = try_partitioning parameters handler error rename_site_inverse mvbdu in match output with \| None -> error , ( handler , No_known_translation list ) \| Some ( var , l ) -> error , ( handler , Partition ( var , l ) ) end end else error , ( handler , No_known_translation list )
let rec print ? beginning_of_sentence ( : beggining = true ) ? prompt_agent_type ( : prompt_agent_type = true ) ? html_mode ( : html_mode = false ) ~ show_dep_with_dimmension_higher_than : dim_min parameters handler_kappa error agent_string agent_type agent_id translation t = let tab = if html_mode then " < PRE > </ PRE " > else " \ t " in let endofline = if html_mode then " < Br >\ n " else " \ n " in let beginenumeration = if html_mode then " < UL >\ n " else " " in let endenumeration = if html_mode then " </ UL >\ n " else " " in let beginenum = if html_mode then " < LI " > else " " + in let endenum = if html_mode then " </ LI >\ n " else " " in let cap s = if beggining then Tools . capitalize s else s in let in_agent s = if prompt_agent_type then " in agent " ^ s " ^ " else " " in let in_agent_comma s = if prompt_agent_type then " in agent " ^ s " , ^ " else " " in let log = Remanent_parameters . get_logger parameters in let error , ( ) = match translation with \| Range ( site_type , state_list ) -> begin if dim_min <= 1 then begin match Remanent_parameters . get_backend_mode parameters with \| Remanent_parameters_sig . Kappa \| Remanent_parameters_sig . Raw -> let error , t = Site_graphs . KaSa_site_graph . add_site parameters error handler_kappa agent_id site_type t in let error = Site_graphs . KaSa_site_graph . print log parameters error t in let ( ) = Loggers . fprintf log " => " in let should_use_bracket = match state_list with \| [ ] \| [ _ ] -> false \| _ :: _ -> true in let ( ) = if should_use_bracket then Loggers . fprintf log " [ " in let error , _bool = List . fold_left ( fun ( error , bool ) state -> let ( ) = if bool then Loggers . fprintf log " v " in let error , t = Site_graphs . KaSa_site_graph . add_state parameters error handler_kappa agent_id site_type state t in let error = Site_graphs . KaSa_site_graph . print log parameters error t in error , true ) ( error , false ) state_list in let ( ) = if should_use_bracket then Loggers . fprintf log " ] " in let ( ) = Loggers . print_newline log in error , ( ) \| Remanent_parameters_sig . Natural_language -> let error ' , site_string = Handler . string_of_site_in_natural_language parameters error handler_kappa agent_type site_type in let error = Exception . check_point Exception . warn parameters error error ' __POS__ Exit in let rec aux list error = match list with \| [ ] -> Exception . warn parameters error __POS__ Exit ( ) \| [ state ] -> let error ' , state_string = Handler . string_of_state_fully_deciphered parameters error handler_kappa agent_type site_type state in let error = Exception . check_point Exception . warn parameters error error ' __POS__ Exit in error , Loggers . fprintf log " and % s . % s " state_string endofline \| state :: tail -> let error ' , state_string = Handler . string_of_state_fully_deciphered parameters error handler_kappa agent_type site_type state in let error = Exception . check_point Exception . warn parameters error error ' __POS__ Exit in let ( ) = Loggers . fprintf log " % s , " state_string in aux tail error in match state_list with \| [ ] -> Exception . warn parameters error __POS__ Exit ( ) \| [ state ] -> let error ' , state_string = Handler . string_of_state_fully_deciphered parameters error handler_kappa agent_type site_type state in let error = Exception . check_point Exception . warn parameters error error ' __POS__ Exit in error , Loggers . fprintf log " % s % s % sis always % s . % s " ( Remanent_parameters . get_prefix parameters ) ( cap site_string ) ( in_agent agent_string ) state_string endofline \| [ state1 ; state2 ] -> let error ' , state_string1 = Handler . string_of_state_fully_deciphered parameters error handler_kappa agent_type site_type state1 in let error = Exception . check_point Exception . warn parameters error error ' __POS__ Exit in let error ' , state_string2 = Handler . string_of_state_fully_deciphered parameters error handler_kappa agent_type site_type state2 in let error = Exception . check_point Exception . warn parameters error error ' __POS__ Exit in error , Loggers . fprintf log " % s % s % sranges over % s and % s . % s " ( Remanent_parameters . get_prefix parameters ) ( cap site_string ) ( in_agent agent_string ) state_string1 state_string2 endofline \| list -> let ( ) = Loggers . fprintf log " % s % s % sranges over " ( Remanent_parameters . get_prefix parameters ) ( cap site_string ) ( in_agent agent_string ) in aux list error end else error , ( ) end \| Equiv ( ( site1 , state1 ) , ( site2 , state2 ) ) -> if dim_min <= 2 then begin match Remanent_parameters . get_backend_mode parameters with \| Remanent_parameters_sig . Kappa \| Remanent_parameters_sig . Raw -> let error , t ' = Site_graphs . KaSa_site_graph . add_state parameters error handler_kappa agent_id site1 state1 t in let error , t ' ' = Site_graphs . KaSa_site_graph . add_state parameters error handler_kappa agent_id site2 state2 t in let error = Site_graphs . KaSa_site_graph . print ( Remanent_parameters . get_logger parameters ) parameters error t ' in let ( ) = Loggers . fprintf ( Remanent_parameters . get_logger parameters ) " <=> " in let error = Site_graphs . KaSa_site_graph . print ( Remanent_parameters . get_logger parameters ) parameters error t ' ' in let ( ) = Loggers . print_newline ( Remanent_parameters . get_logger parameters ) in error , ( ) \| Remanent_parameters_sig . Natural_language -> let error ' , site_string1 = Handler . string_of_site_in_natural_language parameters error handler_kappa agent_type site1 in let error = Exception . check_point Exception . warn parameters error error ' __POS__ Exit in let error ' , state_string1 = Handler . string_of_state_fully_deciphered parameters error handler_kappa agent_type site1 state1 in let error = Exception . check_point Exception . warn parameters error error ' __POS__ Exit in let error ' , site_string2 = Handler . string_of_site_in_natural_language parameters error handler_kappa agent_type site2 in let error = Exception . check_point Exception . warn parameters error error ' __POS__ Exit in let error ' , state_string2 = Handler . string_of_state_fully_deciphered parameters error handler_kappa agent_type site2 state2 in let error = Exception . check_point Exception . warn parameters error error ' __POS__ Exit in error , Loggers . fprintf ( Remanent_parameters . get_logger parameters ) " % s % s % s is % s , if and only if , % s is % s . % s " ( Remanent_parameters . get_prefix parameters ) ( cap ( in_agent_comma agent_string ) ) site_string1 state_string1 site_string2 state_string2 endofline end else error , ( ) \| Imply ( ( site1 , state1 ) , ( site2 , state2 ) ) -> if dim_min <= 2 then begin match Remanent_parameters . get_backend_mode parameters with \| Remanent_parameters_sig . Kappa \| Remanent_parameters_sig . Raw -> let error , t = Site_graphs . KaSa_site_graph . add_state parameters error handler_kappa agent_id site1 state1 t in let error , t ' = Site_graphs . KaSa_site_graph . add_state parameters error handler_kappa agent_id site2 state2 t in let error = Site_graphs . KaSa_site_graph . print ( Remanent_parameters . get_logger parameters ) parameters error t in let ( ) = Loggers . fprintf ( Remanent_parameters . get_logger parameters ) " => " in let error = Site_graphs . KaSa_site_graph . print ( Remanent_parameters . get_logger parameters ) parameters error t ' in let ( ) = Loggers . print_newline ( Remanent_parameters . get_logger parameters ) in error , ( ) \| Remanent_parameters_sig . Natural_language -> let error ' , site_string1 = Handler . string_of_site_in_natural_language parameters error handler_kappa agent_type site1 in let error = Exception . check_point Exception . warn parameters error error ' __POS__ Exit in let error ' , state_string1 = Handler . string_of_state_fully_deciphered parameters error handler_kappa agent_type site1 state1 in let error = Exception . check_point Exception . warn parameters error error ' __POS__ Exit in let error ' , site_string2 = Handler . string_of_site_in_natural_language parameters error handler_kappa agent_type site2 in let error = Exception . check_point Exception . warn parameters error error ' __POS__ Exit in let error ' , state_string2 = Handler . string_of_state_fully_deciphered parameters error handler_kappa agent_type site2 state2 in let error = Exception . check_point Exception . warn parameters error error ' __POS__ Exit in error , Loggers . fprintf ( Remanent_parameters . get_logger parameters ) " % s % s % s is % s whenever % s is % s . % s " ( Remanent_parameters . get_prefix parameters ) ( cap ( in_agent_comma agent_string ) ) site_string2 state_string2 site_string1 state_string1 endofline end else error , ( ) \| Partition ( v , list ) -> let error , site_string = Handler . string_of_site_in_natural_language parameters error handler_kappa agent_type v in let parameters = Remanent_parameters . update_prefix parameters tab in let error = List . fold_left ( fun error ( a , list ) -> let error , parameters = match Remanent_parameters . get_backend_mode parameters with \| Remanent_parameters_sig . Natural_language -> let error , state_string = Handler . string_of_state_fully_deciphered parameters error handler_kappa agent_type v a in let ( ) = Loggers . fprintf log " % swhen % s is equal to % s , then :% s % s " ( Remanent_parameters . get_prefix parameters ) site_string state_string endofline beginenumeration in let parameters = Remanent_parameters . update_prefix parameters ( tab ^ beginenum ^ " " ) in error , parameters \| Remanent_parameters_sig . Kappa \| Remanent_parameters_sig . Raw -> error , parameters in let error , t ' = Site_graphs . KaSa_site_graph . add_state parameters error handler_kappa agent_id v a t in let error = List . fold_left ( fun error token -> let error = print ~ beginning_of_sentence : false ~ prompt_agent_type : false ~ html_mode ~ show_dep_with_dimmension_higher_than : 0 parameters handler_kappa error agent_string agent_type agent_id token t ' in let ( ) = Loggers . fprintf log " % s " endenum in error ) error list in let ( ) = Loggers . fprintf log " % s " endenumeration in error ) error list in error , ( ) \| No_known_translation list -> begin match Remanent_parameters . get_backend_mode parameters with \| Remanent_parameters_sig . Kappa \| Remanent_parameters_sig . Raw -> begin let error = Site_graphs . KaSa_site_graph . print log parameters error t in let prefix " = " in let ( ) = Loggers . fprintf log " =>\ n % s [ \ n " prefix in let prefix ' = prefix in let prefix " =\ t " in let error , _bool = List . fold_left ( fun ( error , bool ) state_list -> let ( ) = Loggers . fprintf log " % s % s " prefix ( if bool then " v " else " " ) in let error , t ' = List . fold_left ( fun ( error , t ) ( site , state ) -> Site_graphs . KaSa_site_graph . add_state parameters error handler_kappa agent_id site state t ) ( error , t ) state_list in let error = Site_graphs . KaSa_site_graph . print log parameters error t ' in let ( ) = Loggers . print_newline log in ( error , true ) ) ( error , false ) list in let ( ) = Loggers . fprintf log " % s ] \ n " prefix ' in error , ( ) end \| Remanent_parameters_sig . Natural_language -> begin match list with \| [ ] -> error , ( ) \| head :: _ -> let n = List . length head in if n >= dim_min then let ( ) = Loggers . fprintf log " % s % s " ( Remanent_parameters . get_prefix parameters ) ( cap ( in_agent_comma agent_string ) ) in let error , ( ) = let rec aux l error = match l with \| [ a , _ ] -> let error , string = Handler . string_of_site_in_natural_language parameters error handler_kappa agent_type a in let ( ) = Loggers . fprintf log " , and % s , " string in error , ( ) \| [ ] -> Exception . warn parameters error __POS__ Exit ( ) \| ( a , _ ) :: b -> let error , string = Handler . string_of_site_in_natural_language parameters error handler_kappa agent_type a in let ( ) = Loggers . fprintf log " , % s " string in aux b error in match head with \| [ ] \| [ _ ] -> Exception . warn parameters error __POS__ Exit ( ) \| ( a , _ ) :: b -> let error , string = Handler . string_of_site_in_natural_language parameters error handler_kappa agent_type a in let ( ) = Loggers . fprintf log " % s " string in aux b error in let ( ) = Loggers . fprintf log " are entangled by the following % i - d relationship :% s " n endofline in let parameters = Remanent_parameters . update_prefix parameters " \ t " in List . fold_left ( fun error l -> let error , bool = List . fold_left ( fun ( error , bool ) ( site_type , state ) -> let error ' , site_string = Handler . string_of_site parameters error handler_kappa agent_type site_type in let error = Exception . check_point Exception . warn parameters error error ' __POS__ Exit in let error ' , state_string = Handler . string_of_state_fully_deciphered parameters error handler_kappa agent_type site_type state in let error = Exception . check_point Exception . warn parameters error error ' __POS__ Exit in let ( ) = if bool then Loggers . fprintf log " , " else Loggers . fprintf log " % s % s ( " ( Remanent_parameters . get_prefix parameters ) agent_string in let ( ) = Loggers . fprintf log " % s % s " site_string state_string in error , true ) ( error , false ) l in let ( ) = if bool then Loggers . fprintf log " ) % s " endofline in error ) error list , ( ) else error , ( ) end end in error
let rec convert_views_internal_constraints_list_aux ~ show_dep_with_dimmension_higher_than : dim_min parameters handler_kappa error agent_string agent_type agent_id translation t current_list = let error , current_list = match translation with \| Range ( site_type , state_list ) -> begin if dim_min <= 1 then begin match Remanent_parameters . get_backend_mode parameters with \| Remanent_parameters_sig . Kappa \| Remanent_parameters_sig . Raw -> let error , t = Site_graphs . KaSa_site_graph . add_site parameters error handler_kappa agent_id site_type t in let error ' ' , refinement = List . fold_left ( fun ( error , c_list ) state -> let error ' , t ' = Site_graphs . KaSa_site_graph . add_state parameters error handler_kappa agent_id site_type state t in let error = Exception . check_point Exception . warn parameters error error ' __POS__ Exit in error , t ' :: c_list ) ( error , [ ] ) state_list in let lemma = { Public_data . hyp = t ; Public_data . refinement = refinement } in let current_list = lemma :: current_list in let error = Exception . check_point Exception . warn parameters error error ' ' __POS__ Exit in error , current_list \| Remanent_parameters_sig . Natural_language -> error , current_list end else error , current_list end \| Equiv ( ( site1 , state1 ) , ( site2 , state2 ) ) -> if dim_min <= 2 then begin match Remanent_parameters . get_backend_mode parameters with \| Remanent_parameters_sig . Kappa \| Remanent_parameters_sig . Raw -> let error ' , t ' = Site_graphs . KaSa_site_graph . add_state parameters error handler_kappa agent_id site1 state1 t in let error = Exception . check_point Exception . warn parameters error error ' __POS__ Exit in let error ' ' ' , t ' ' = Site_graphs . KaSa_site_graph . add_state parameters error handler_kappa agent_id site2 state2 t in let error = Exception . check_point Exception . warn parameters error error ' ' ' __POS__ Exit in let lemma = { Public_data . hyp = t ' ; Public_data . refinement = [ t ' ' ] } in let current_list = lemma :: current_list in error , List . rev current_list \| Remanent_parameters_sig . Natural_language -> error , current_list end else error , current_list \| Imply ( ( site1 , state1 ) , ( site2 , state2 ) ) -> if dim_min <= 2 then begin match Remanent_parameters . get_backend_mode parameters with \| Remanent_parameters_sig . Kappa \| Remanent_parameters_sig . Raw -> let error ' , t = Site_graphs . KaSa_site_graph . add_state parameters error handler_kappa agent_id site1 state1 t in let error = Exception . check_point Exception . warn parameters error error ' __POS__ Exit in let error ' ' ' , t ' = Site_graphs . KaSa_site_graph . add_state parameters error handler_kappa agent_id site2 state2 t in let error = Exception . check_point Exception . warn parameters error error ' ' ' __POS__ Exit in let lemma = { Public_data . hyp = t ; Public_data . refinement = [ t ' ] } in let current_list = lemma :: current_list in error , List . rev current_list \| Remanent_parameters_sig . Natural_language -> error , current_list end else error , current_list \| Partition ( site_type , list ) -> let error , current_list = List . fold_left ( fun ( error , current_list ) ( state , list ) -> let error ' , t ' = Site_graphs . KaSa_site_graph . add_state parameters error handler_kappa agent_id site_type state t in let error = Exception . check_point Exception . warn parameters error error ' __POS__ Exit in let error ' ' , current_list = List . fold_left ( fun ( error , current_list ) token -> convert_views_internal_constraints_list_aux ~ show_dep_with_dimmension_higher_than : 0 parameters handler_kappa error agent_string agent_type agent_id token t ' current_list ) ( error , current_list ) list in let error = Exception . check_point Exception . warn parameters error error ' ' __POS__ Exit in error , current_list ) ( error , current_list ) list in error , current_list \| No_known_translation list -> begin match Remanent_parameters . get_backend_mode parameters with \| Remanent_parameters_sig . Kappa \| Remanent_parameters_sig . Raw -> begin let error , current_list = let error ' ' , refinement = List . fold_left ( fun ( error , current_list ) state_list -> let error , t ' = List . fold_left ( fun ( error , t ' ) ( site , state ) -> let error ' , t ' = Site_graphs . KaSa_site_graph . add_state parameters error handler_kappa agent_id site state t ' in let error = Exception . check_point Exception . warn parameters error error ' __POS__ Exit in error , t ' ) ( error , t ) state_list in let refinement = t ' :: current_list in error , refinement ) ( error , [ ] ) list in let error = Exception . check_point Exception . warn parameters error error ' ' __POS__ Exit in let lemma = { Public_data . hyp = t ; Public_data . refinement = refinement } in let current_list = lemma :: current_list in error , current_list in error , current_list end \| Remanent_parameters_sig . Natural_language -> error , current_list end in error , current_list
let convert_views_internal_constraints_list ~ show_dep_with_dimmension_higher_than : dim_min parameters handler_kappa error agent_string agent_type translation current_list = let t = Site_graphs . KaSa_site_graph . empty in let error ' , agent_id , t = Site_graphs . KaSa_site_graph . add_agent parameters error handler_kappa agent_type t in let error = Exception . check_point Exception . warn parameters error error ' __POS__ Exit in let error , t = match translation with \| Range ( site , _ ) -> Site_graphs . KaSa_site_graph . add_site parameters error handler_kappa agent_id site t \| Equiv _ \| Imply _ \| Partition _ \| No_known_translation _ -> error , t in convert_views_internal_constraints_list_aux ~ show_dep_with_dimmension_higher_than : dim_min parameters handler_kappa error agent_string agent_type agent_id translation t current_list
let print ? beginning_of_sentence ( : beggining = true ) ? prompt_agent_type ( : prompt_agent_type = true ) ? html_mode ( : html_mode = false ) ~ show_dep_with_dimmension_higher_than : dim_min parameters handler_kappa error agent_string agent_type translation = let t = Site_graphs . KaSa_site_graph . empty in let error , id , t = Site_graphs . KaSa_site_graph . add_agent parameters error handler_kappa agent_type t in print ~ beginning_of_sentence : beggining ~ prompt_agent_type ~ html_mode ~ show_dep_with_dimmension_higher_than : dim_min parameters handler_kappa error agent_string agent_type id translation t
exception Internal_error of [ ` Cannot_parse of exn \| ` Ast_changed \| ` Doc_comment of Normalize . docstring_error list \| ` Comment \| ` Comment_dropped of Cmt . t list \| ` Warning50 of ( Location . t * Warnings . t ) list ] * ( string * Sexp . t ) list
let internal_error msg kvs = raise ( Internal_error ( msg , kvs ) )
type error = \| Invalid_source of { exn : exn } \| Unstable of { iteration : int ; prev : string ; next : string } \| Ocamlformat_bug of { exn : exn } \| User_error of string
let ellipsis n msg = let msg = String . strip msg in if n > 0 && String . length msg > ( n * 2 ) + 10 then Format . sprintf " % s . . . % s " ( String . prefix msg n ) ( String . suffix msg n ) else msg
let ellipsis_cmt = ellipsis 50
let with_file input_name output_file suf ext f = let dir = match output_file with \| Some filename -> Filename . dirname filename \| None -> Filename . get_temp_dir_name ( ) in let base = Filename . remove_extension ( Filename . basename input_name ) in let tmp = Filename . concat dir ( base ^ suf ^ ext ) in Out_channel . with_file tmp ~ f ; tmp
let dump_ast ~ input_name ? output_file ~ suffix fmt = let ext = " . ast " in with_file input_name output_file suffix ext ( fun oc -> fmt ( Format . formatter_of_out_channel oc ) )
let dump_formatted ~ input_name ? output_file ~ suffix fmted = let ext = Filename . extension input_name in with_file input_name output_file suffix ext ( fun oc -> Out_channel . output_string oc fmted )
let print_error ~ fmt ~ exe ~ debug ~ quiet ~ input_name error = match error with \| Invalid_source _ when quiet -> ( ) \| Invalid_source { exn } -> ( let reason = match exn with \| Syntaxerr . Error _ \| Lexer . Error _ -> " ( syntax error ) " \| Warning50 _ -> " ( misplaced documentation comments - warning 50 ) " \| _ -> " " in Format . fprintf fmt " % s : ignoring % S % s \ n " %! exe input_name reason ; match exn with \| Syntaxerr . Error _ \| Lexer . Error _ -> Location . report_exception fmt exn \| Warning50 l -> List . iter l ~ f ( : fun ( l , w ) -> print_warning l w ) ; Format . fprintf fmt " { @< warning > Hint } @: ( Warning 50 ) This file contains a \ documentation comment that the OCaml compiler does \ not know how to attach to the AST . OCamlformat does not \ support these cases . You can find more information at : \ https :// github . com / ocaml - ppx / ocamlformat # overview . If you ' d \ like to disable this check and let ocamlformat make a choice \ ( though it might not be consistent with the ocaml compilers \ and odoc ) , you can set the -- no - comment - check option . \ n \ " %! \| exn -> Format . fprintf fmt " % s \ n " %! ( Exn . to_string exn ) ) \| Unstable { iteration ; prev ; next } -> if debug then ( let ext = Filename . extension input_name in let input_name = Filename . chop_extension ( Filename . basename input_name ) in let p = Filename . temp_file input_name ( Printf . sprintf " . prev % s " ext ) in Out_channel . write_all p ~ data : prev ; let n = Filename . temp_file input_name ( Printf . sprintf " . next % s " ext ) in Out_channel . write_all n ~ data : next ; ignore ( Unix . system ( Printf . sprintf " diff % S % S 1 >& 2 " p n ) ) ; Unix . unlink p ; Unix . unlink n ) ; if iteration <= 1 then Format . fprintf fmt " % s : % S was not already formatted . ( [ max - iters = 1 ] ) \ n " %! exe input_name else ( Format . fprintf fmt " % s : Cannot process % S . \ n \ \ Please report this bug at \ https :// github . com / ocaml - ppx / ocamlformat / issues . \ n \ " %! exe input_name ; Format . fprintf fmt " BUG : formatting did not stabilize after % i iterations . \ n " %! iteration ) \| User_error msg -> Format . fprintf fmt " % s : % s . \ n " %! exe msg \| Ocamlformat_bug { exn } -> ( Format . fprintf fmt " % s : Cannot process % S . \ n \ \ Please report this bug at \ https :// github . com / ocaml - ppx / ocamlformat / issues . \ n \ " %! exe input_name ; match exn with \| Internal_error ( m , l ) -> let s = match m with \| ` Cannot_parse _ -> " generating invalid ocaml syntax " \| ` Ast_changed -> " ast changed " \| ` Doc_comment _ -> " doc comments changed " \| ` Comment -> " comments changed " \| ` Comment_dropped _ -> " comments dropped " \| ` Warning50 _ -> " misplaced documentation comments " in Format . fprintf fmt " BUG : % s . \ n " %! s ; ( match m with \| ` Doc_comment l when not quiet -> List . iter l ~ f ( : function \| Normalize . Moved ( loc_before , loc_after , msg ) -> if Location . compare loc_before Location . none = 0 then Format . fprintf fmt " { %!@< loc >% a } , @:@\ { @< error > Error } @: Docstring added . \ n \ " %! Location . print loc_after ( ellipsis_cmt msg ) else if Location . compare loc_after Location . none = 0 then Format . fprintf fmt " { %!@< loc >% a } , @:@\ { @< error > Error } @: Docstring dropped . \ n \ " %! Location . print loc_before ( ellipsis_cmt msg ) else Format . fprintf fmt " { %!@< loc >% a } , @:@\ { @< error > Error } @: Docstring moved to \ { @< loc >% a } . @\ n \ " %! Location . print loc_before ( ellipsis_cmt msg ) Location . print loc_after \| Normalize . Unstable ( loc , s ) -> Format . fprintf fmt " { %!@< loc >% a } , @:@\ { @< error > Error } @: Formatting of is \ unstable ( e . g . parses as a list or not depending on \ the margin ) , please tighten up this comment in the \ source or disable the formatting using the option \ -- no - parse - docstrings . \ n \ " %! Location . print loc ( ellipsis_cmt s ) ) \| ` Comment_dropped l when not quiet -> List . iter l ~ f ( : fun Cmt . { txt = msg ; loc } -> Format . fprintf fmt " { %!@< loc >% a } , @:@\ { @< error > Error } @: Comment dropped . \ n \ " %! Location . print loc ( ellipsis_cmt msg ) ) \| ` Cannot_parse ( ( Syntaxerr . Error _ \| Lexer . Error _ ) as exn ) -> if debug then Location . report_exception fmt exn \| ` Warning50 l -> if debug then List . iter l ~ f ( : fun ( l , w ) -> print_warning l w ) \| _ -> ( ) ) ; if debug then List . iter l ~ f ( : fun ( msg , sexp ) -> Format . fprintf fmt " % s : % s \ n " %! msg ( Sexp . to_string sexp ) ) \| exn -> Format . fprintf fmt " BUG : unhandled exception . Use [ -- debug ] for details . \ n " %! ; if debug then Format . fprintf fmt " % s \ n " %! ( Exn . to_string exn ) )
let check_all_locations fmt cmts_t = match Cmts . remaining_locs cmts_t with \| [ ] -> ( ) \| l -> let print l = Format . fprintf fmt " % a \ n " %! Location . print l in Format . fprintf fmt " Warning : Some locations have not been considered \ n " %! ; List . iter ~ f : print ( List . sort l ~ compare : Location . compare )
let check_margin conf ~ filename ~ fmted = List . iteri ( String . split_lines fmted ) ~ f ( : fun i line -> if String . length line > conf . Conf . margin then Format . fprintf Format . err_formatter " Warning : % s :% i exceeds the margin \ n " %! filename i )
let with_optional_box_debug ~ box_debug k = if box_debug then Fmt . with_box_debug k else k
let with_buffer_formatter ~ buffer_size k = let buffer = Buffer . create buffer_size in let fs = Format_ . formatter_of_buffer buffer in Fmt . eval fs k ; Format_ . pp_print_flush fs ( ) ; if Buffer . length buffer > 0 then Format_ . pp_print_newline fs ( ) ; Buffer . contents buffer
let equal fragment ~ ignore_doc_comments c a b = Normalize . equal fragment ~ ignore_doc_comments c a . Parse_with_comments . ast b . Parse_with_comments . ast
let normalize fragment c { Parse_with_comments . ast ; _ } = Normalize . normalize fragment c ast
let recover ( type a ) : a Traverse . fragment -> _ = function \| Traverse . Structure -> Parse_wyc . Make_parsable . structure \| Traverse . Signature -> Parse_wyc . Make_parsable . signature \| Traverse . Use_file -> Parse_wyc . Make_parsable . use_file
let format fragment ? output_file ~ input_name ~ prev_source ~ parsed conf opts = let open Result . Monad_infix in let dump_ast ~ suffix ast = if opts . Conf . debug then Some ( dump_ast ~ input_name ? output_file ~ suffix ( fun fmt -> Migrate_ast . Printast . fragment fragment fmt ast ) ) else None in let dump_formatted ~ suffix fmted = if opts . debug then Some ( dump_formatted ~ input_name ? output_file ~ suffix fmted ) else None in Ocaml_common . Location . input_name := input_name ; let rec print_check ~ i ( ~ conf : Conf . t ) ~ prev_source t = let format ~ box_debug = let open Fmt in let cmts_t = Cmts . init fragment ~ debug : opts . debug t . source t . ast t . comments in let contents = with_buffer_formatter ~ buffer_size ( : String . length prev_source ) ( set_margin conf . margin $ opt conf . max_indent set_max_indent $ fmt_if_k ( not ( String . is_empty t . prefix ) ) ( str t . prefix $ fmt " . " ) @ $ with_optional_box_debug ~ box_debug ( Fmt_ast . fmt_fragment fragment ~ debug : opts . debug t . source cmts_t conf t . ast ) ) in ( contents , cmts_t ) in if opts . debug then format ~ box_debug : true \|> fst \|> dump_formatted ~ suffix " . : boxes " \|> ( ignore : string option -> unit ) ; let fmted , cmts_t = format ~ box_debug : false in let conf = if opts . debug then conf else { conf with Conf . quiet = true } in if String . equal prev_source fmted then ( if opts . debug then check_all_locations Format . err_formatter cmts_t ; if opts . Conf . margin_check then check_margin conf ~ fmted ~ filename ( : Option . value output_file ~ default : input_name ) ; Ok fmted ) else let exn_args ( ) = [ ( " output file " , dump_formatted ~ suffix " . : invalid - ast " fmted ) ] \|> List . filter_map ~ f ( : fun ( s , f_opt ) -> Option . map f_opt ~ f ( : fun f -> ( s , String . sexp_of_t f ) ) ) in ( match parse fragment conf ~ source : fmted with \| exception Sys_error msg -> Error ( User_error msg ) \| exception Warning50 l -> internal_error ( ` Warning50 l ) ( exn_args ( ) ) \| exception exn -> if opts . Conf . format_invalid_files then ( match parse fragment conf ~ source ( : recover fragment fmted ) with \| exception exn -> internal_error ( ` Cannot_parse exn ) ( exn_args ( ) ) \| t_new -> Format . fprintf Format . err_formatter " Warning : % s is invalid , recovering . \ n " %! input_name ; Ok t_new ) else internal_error ( ` Cannot_parse exn ) ( exn_args ( ) ) \| t_new -> Ok t_new ) >>= fun t_new -> ( if not ( equal fragment ~ ignore_doc_comments ( : not conf . comment_check ) conf t t_new ) then let old_ast = dump_ast ~ suffix " . : old " ( normalize fragment conf t ) in let new_ast = dump_ast ~ suffix " . : new " ( normalize fragment conf t_new ) in let args ~ suffix = [ ( " output file " , dump_formatted ~ suffix fmted ) ; ( " old ast " , old_ast ) ; ( " new ast " , new_ast ) ] \|> List . filter_map ~ f ( : fun ( s , f_opt ) -> Option . map f_opt ~ f ( : fun f -> ( s , String . sexp_of_t f ) ) ) in if equal fragment ~ ignore_doc_comments : true conf t t_new then let docstrings = Normalize . moved_docstrings fragment conf t . Parse_with_comments . ast t_new . Parse_with_comments . ast in let args = args ~ suffix " . : unequal - docs " in internal_error ( ` Doc_comment docstrings ) args else let args = args ~ suffix " . : unequal - ast " in internal_error ` Ast_changed args ) ; if conf . comment_check then ( ( match Cmts . remaining_comments cmts_t with \| [ ] -> ( ) \| l -> internal_error ( ` Comment_dropped l ) [ ] ) ; let is_docstring Cmt . { txt ; _ } = conf . parse_docstrings && Char . equal txt . [ 0 ] ' ' * in let old_docstrings , old_comments = List . partition_tf t . comments ~ f : is_docstring in let t_newdocstrings , t_newcomments = List . partition_tf t_new . comments ~ f : is_docstring in let f = ellipsis_cmt in let f x = Either . First . map ~ f x \|> Either . Second . map ~ f in let diff_cmts = Sequence . append ( Cmts . diff conf old_comments t_newcomments ) ( Fmt_odoc . diff conf old_docstrings t_newdocstrings ) \|> Sequence . map ~ f in if not ( Sequence . is_empty diff_cmts ) then let old_ast = dump_ast ~ suffix " . : old " t . ast in let new_ast = dump_ast ~ suffix " . : new " t_new . ast in let args = [ ( " diff " , Some ( Sequence . sexp_of_t ( Either . sexp_of_t String . sexp_of_t String . sexp_of_t ) diff_cmts ) ) ; ( " old ast " , Option . map old_ast ~ f : String . sexp_of_t ) ; ( " new ast " , Option . map new_ast ~ f : String . sexp_of_t ) ] \|> List . filter_map ~ f ( : fun ( s , f_opt ) -> Option . map f_opt ~ f ( : fun f -> ( s , f ) ) ) in internal_error ` Comment args ) ; if i >= conf . max_iters then ( Caml . flush_all ( ) ; Error ( Unstable { iteration = i ; prev = prev_source ; next = fmted } ) ) else print_check ~ i ( : i + 1 ) ~ conf ~ prev_source : fmted t_new in try print_check ~ i : 1 ~ conf ~ prev_source parsed with \| Sys_error msg -> Error ( User_error msg ) \| exn -> Error ( Ocamlformat_bug { exn } )
let parse_result fragment conf ( opts : Conf . opts ) ~ source ~ input_name = match parse fragment conf ~ source with \| exception exn -> if opts . format_invalid_files then ( match parse fragment conf ~ source ( : recover fragment source ) with \| exception exn -> Error ( Invalid_source { exn } ) \| parsed -> Format . fprintf Format . err_formatter " Warning : % s is invalid , recovering . \ n " %! input_name ; Ok parsed ) else Error ( Invalid_source { exn } ) \| parsed -> Ok parsed
let parse_and_format fragment ? output_file ~ input_name ~ source conf opts = Ocaml_common . Location . input_name := input_name ; let open Result . Monad_infix in parse_result fragment conf opts ~ source ~ input_name >>= fun parsed -> format fragment ? output_file ~ input_name ~ prev_source : source ~ parsed conf opts
module Config = struct type config = { generator_config : Michelson_generation . generator_config ; michelson_terms_file : string option ; } let default_config = { generator_config = Michelson_generation . default_generator_config ; michelson_terms_file = None ; } let config_encoding = let open Data_encoding in conv ( fun { generator_config ; michelson_terms_file } -> ( generator_config , michelson_terms_file ) ) ( fun ( generator_config , michelson_terms_file ) -> { generator_config ; michelson_terms_file } ) ( obj2 ( req " generator_config " Michelson_generation . generator_config_encoding ) ( opt " michelson_terms_file " string ) ) end
module Default_boilerplate = struct type workload = Translator_workload . t let workload_encoding = Translator_workload . encoding let workload_to_vector = Translator_workload . workload_to_sparse_vec let tags = [ Tags . translator ] let make_models t_kind code_or_data = [ ( " gas_translator_model " , Translator_model . gas_based_model t_kind code_or_data ) ; ( " size_translator_model " , Translator_model . size_based_model t_kind code_or_data ) ; ] end
type phase = Workload_production \| In_protocol \| Global
type error_kind = \| Global_error of { benchmark_name : string ; workload : Tezos_base . TzPervasives . tztrace ; } \| Bad_data of { benchmark_name : string ; micheline : Alpha_context . Script . expr ; expected_type : Alpha_context . Script . expr ; phase : phase ; } \| Bad_code of { benchmark_name : string ; micheline : Alpha_context . Script . expr ; expected_stack_type : Alpha_context . Script . expr list ; phase : phase ; }
let pp_phase fmtr ( phase : phase ) = match phase with \| Workload_production -> Format . fprintf fmtr " workload production " \| In_protocol -> Format . fprintf fmtr " in protocol " \| Global -> Format . fprintf fmtr " global "
let report_michelson_errors fmtr errs = Michelson_v1_error_reporter . report_errors ~ details : true ~ show_source : true fmtr errs
let make_printable node = Micheline_printer . printable Michelson_v1_primitives . string_of_prim node
let pp_error_kind fmtr ( error_kind : error_kind ) = match error_kind with \| Global_error { benchmark_name ; workload } -> Format . open_vbox 1 ; Format . fprintf fmtr " Global error , " :@ ; Format . fprintf fmtr " benchmark = % s , " @ benchmark_name ; Format . fprintf fmtr " workload , " :@ ; report_michelson_errors fmtr workload ; Format . close_box ( ) \| Bad_data { benchmark_name ; micheline ; expected_type ; phase } -> Format . open_vbox 1 ; Format . fprintf fmtr " Bad data , " :@ ; Format . fprintf fmtr " benchmark = % s , " @ benchmark_name ; Format . fprintf fmtr " expression = [ @< v 1 >% a ] , " @@ Micheline_printer . print_expr ( make_printable micheline ) ; Format . fprintf fmtr " expected type = [ @< v 1 >% a ] , " @@ Micheline_printer . print_expr ( make_printable expected_type ) ; Format . fprintf fmtr " phase = % a , " @ pp_phase phase ; Format . close_box ( ) \| Bad_code { benchmark_name ; micheline ; expected_stack_type ; phase } -> Format . open_vbox 1 ; Format . fprintf fmtr " Bad code , " :@ ; Format . fprintf fmtr " benchmark = % s , " @ benchmark_name ; Format . fprintf fmtr " expression = [ @< v 1 >% a ] , " @@ Micheline_printer . print_expr ( make_printable micheline ) ; Format . fprintf fmtr " expected stack = [ @< v 1 >% a ] , " @@ ( Format . pp_print_list ~ pp_sep ( : fun fmtr ( ) -> Format . fprintf fmtr " " ) :: ( fun fmtr node -> let printable = make_printable node in Format . fprintf fmtr " % a " Micheline_printer . print_expr printable ) ) expected_stack_type ; Format . fprintf fmtr " phase = % a , " @ pp_phase phase ; Format . close_box ( )
let ( ) = Printexc . register_printer ( function \| Translator_benchmark_error err -> Some ( Format . asprintf " % a " pp_error_kind err ) \| _ -> None )
let global_error benchmark_name workload = raise ( Translator_benchmark_error ( Global_error { benchmark_name ; workload } ) )
let bad_data benchmark_name micheline expected_type phase = raise ( Translator_benchmark_error ( Bad_data { benchmark_name ; micheline ; expected_type ; phase } ) )
let bad_code benchmark_name micheline expected_stack_type phase = raise ( Translator_benchmark_error ( Bad_code { benchmark_name ; micheline ; expected_stack_type ; phase } ) )
module Typechecking_data : Benchmark . S = struct include Config include Default_boilerplate let models = make_models Translator_workload . Parsing Translator_workload . Data let name = " TYPECHECKING_DATA " let info = " Benchmarking typechecking of data " let typechecking_data_benchmark rng_state ( node : Protocol . Script_repr . expr ) ( michelson_type : Script_repr . expr ) = Lwt_main . run ( Execution_context . make ~ rng_state >>=? fun ( ctxt , _ ) -> let ex_ty = Type_helpers . michelson_type_to_ex_ty michelson_type ctxt in let workload = match Translator_workload . data_typechecker_workload ctxt Translator_workload . Parsing ( Micheline . root node ) ex_ty with \| None -> bad_data name node michelson_type Workload_production \| Some workload -> workload in match ex_ty with \| Script_ir_translator . Ex_ty ty -> let closure ( ) = match Lwt_main . run ( Script_ir_translator . parse_data ctxt ~ legacy : false ~ allow_forged : false ty ( Micheline . root node ) ) with \| Error _ \| ( exception _ ) -> bad_data name node michelson_type In_protocol \| Ok _ -> ( ) in return ( Generator . Plain { workload ; closure } ) ) \|> function \| Ok closure -> closure \| Error errs -> global_error name errs let make_bench rng_state cfg ( ) = let Michelson_mcmc_samplers . { term ; typ } = Michelson_generation . make_data_sampler rng_state cfg . generator_config in typechecking_data_benchmark rng_state term typ let create_benchmarks ~ rng_state ~ bench_num config = match config . michelson_terms_file with \| Some file -> Format . eprintf " Loading terms from % s . " @ file ; let terms = Michelson_mcmc_samplers . load ~ filename : file in List . filter_map ( function \| Michelson_mcmc_samplers . Data { term ; typ } -> Some ( fun ( ) -> typechecking_data_benchmark rng_state term typ ) \| _ -> None ) terms \| None -> Format . eprintf " No michelson_terms_file given , generating on - the - fly . " @ ; List . repeat bench_num ( make_bench rng_state config ) end
let ( ) = Registration_helpers . register ( module Typechecking_data )
module Unparsing_data : Benchmark . S = struct include Config include Default_boilerplate let models = make_models Translator_workload . Unparsing Translator_workload . Data let name = " UNPARSING_DATA " let info = " Benchmarking unparsing of data " let unparsing_data_benchmark rng_state ( node : Protocol . Script_repr . expr ) ( michelson_type : Protocol . Script_repr . expr ) = Lwt_main . run ( Execution_context . make ~ rng_state >>=? fun ( ctxt , _ ) -> let ex_ty = Type_helpers . michelson_type_to_ex_ty michelson_type ctxt in let workload = match Translator_workload . data_typechecker_workload ctxt Translator_workload . Unparsing ( Micheline . root node ) ex_ty with \| None -> bad_data name node michelson_type Workload_production \| Some workload -> workload in match ex_ty with \| Script_ir_translator . Ex_ty ty -> Script_ir_translator . parse_data ctxt ~ legacy : false ~ allow_forged : false ty ( Micheline . root node ) >\|= Environment . wrap_tzresult >>=? fun ( typed , ctxt ) -> let closure ( ) = match Lwt_main . run ( Script_ir_translator . unparse_data ctxt Script_ir_translator . Optimized ty typed ) with \| Error _ \| ( exception _ ) -> bad_data name node michelson_type In_protocol \| Ok _ -> ( ) in return ( Generator . Plain { workload ; closure } ) ) \|> function \| Ok closure -> closure \| Error errs -> global_error name errs let make_bench rng_state cfg ( ) = let Michelson_mcmc_samplers . { term ; typ } = Michelson_generation . make_data_sampler rng_state cfg . generator_config in unparsing_data_benchmark rng_state term typ let create_benchmarks ~ rng_state ~ bench_num config = match config . michelson_terms_file with \| Some file -> Format . eprintf " Loading terms from % s . " @ file ; let terms = Michelson_mcmc_samplers . load ~ filename : file in List . filter_map ( function \| Michelson_mcmc_samplers . Data { term ; typ } -> Some ( fun ( ) -> unparsing_data_benchmark rng_state term typ ) \| _ -> None ) terms \| None -> Format . eprintf " No michelson_terms_file given , generating on - the - fly . " @ ; List . repeat bench_num ( make_bench rng_state config ) end
let ( ) = Registration_helpers . register ( module Unparsing_data )
module Typechecking_code : Benchmark . S = struct include Config include Default_boilerplate let models = make_models Translator_workload . Parsing Translator_workload . Code let name = " TYPECHECKING_CODE " let info = " Benchmarking typechecking of code " let typechecking_code_benchmark rng_state ( node : Protocol . Script_repr . expr ) ( stack : Script_repr . expr list ) = Lwt_main . run ( Execution_context . make ~ rng_state >>=? fun ( ctxt , _ ) -> let ex_stack_ty = Type_helpers . michelson_type_list_to_ex_stack_ty stack ctxt in let workload = match Translator_workload . code_typechecker_workload ctxt Translator_workload . Parsing ( Micheline . root node ) ex_stack_ty with \| None -> bad_code name node stack Workload_production \| Some workload -> workload in let ( Script_ir_translator . Ex_stack_ty bef ) = ex_stack_ty in let closure ( ) = let result = Lwt_main . run ( Script_ir_translator . parse_instr Script_tc_context . data ctxt ~ legacy : false ( Micheline . root node ) bef ) in match Environment . wrap_tzresult result with \| Error errs -> Format . eprintf " % a . " @ Error_monad . pp_print_trace errs ; bad_code name node stack In_protocol \| Ok _ -> ( ) in return ( Generator . Plain { workload ; closure } ) ) \|> function \| Ok closure -> closure \| Error errs -> global_error name errs let make_bench rng_state ( cfg : Config . config ) ( ) = let open Michelson_generation in let Michelson_mcmc_samplers . { term ; bef ; aft = _ } = make_code_sampler rng_state cfg . generator_config in typechecking_code_benchmark rng_state term bef let create_benchmarks ~ rng_state ~ bench_num config = match config . michelson_terms_file with \| Some file -> Format . eprintf " Loading terms from % s . " @ file ; let terms = Michelson_mcmc_samplers . load ~ filename : file in List . filter_map ( function \| Michelson_mcmc_samplers . Code { term ; bef ; aft = _ } -> Some ( fun ( ) -> typechecking_code_benchmark rng_state term bef ) \| _ -> None ) terms \| None -> Format . eprintf " No michelson_terms_file given , generating on - the - fly . " @ ; List . repeat bench_num ( make_bench rng_state config ) end
let ( ) = Registration_helpers . register ( module Typechecking_code )
module Unparsing_code : Benchmark . S = struct include Config include Default_boilerplate let models = make_models Translator_workload . Unparsing Translator_workload . Code let name = " UNPARSING_CODE " let info = " Benchmarking unparsing of code " let unparsing_code_benchmark rng_state ( node : Protocol . Script_repr . expr ) ( stack : Script_repr . expr list ) = Lwt_main . run ( Execution_context . make ~ rng_state >>=? fun ( ctxt , _ ) -> let ex_stack_ty = Type_helpers . michelson_type_list_to_ex_stack_ty stack ctxt in let workload = match Translator_workload . code_typechecker_workload ctxt Translator_workload . Unparsing ( Micheline . root node ) ex_stack_ty with \| None -> bad_code name node stack Workload_production \| Some workload -> workload in let ( Script_ir_translator . Ex_stack_ty bef ) = ex_stack_ty in Script_ir_translator . parse_instr Script_tc_context . data ctxt ~ legacy : false ( Micheline . root node ) bef >\|= Environment . wrap_tzresult >>=? fun ( _typed , ctxt ) -> let closure ( ) = let result = Lwt_main . run ( Script_ir_translator . unparse_code ctxt Optimized ( Micheline . root node ) ) in match Environment . wrap_tzresult result with \| Error errs -> Format . eprintf " % a . " @ Error_monad . pp_print_trace errs ; bad_code name node stack In_protocol \| Ok _ -> ( ) in return ( Generator . Plain { workload ; closure } ) ) \|> function \| Ok closure -> closure \| Error errs -> global_error name errs let make_bench rng_state ( cfg : Config . config ) ( ) = let open Michelson_generation in let Michelson_mcmc_samplers . { term ; bef ; aft = _ } = make_code_sampler rng_state cfg . generator_config in unparsing_code_benchmark rng_state term bef let create_benchmarks ~ rng_state ~ bench_num config = match config . michelson_terms_file with \| Some file -> Format . eprintf " Loading terms from % s . " @ file ; let terms = Michelson_mcmc_samplers . load ~ filename : file in List . filter_map ( function \| Michelson_mcmc_samplers . Code { term ; bef ; aft = _ } -> Some ( fun ( ) -> unparsing_code_benchmark rng_state term bef ) \| _ -> None ) terms \| None -> List . repeat bench_num ( make_bench rng_state config ) end
let ( ) = Registration_helpers . register ( module Unparsing_code )
let rec check_printable_ascii v i = if Compare . Int . ( i < 0 ) then true else match v . [ i ] with \| ' \ n ' \| ' \ x20 ' . . ' \ x7E ' -> check_printable_ascii v ( i - 1 ) \| _ -> false
let check_printable_benchmark = let open Tezos_shell_benchmarks . Encoding_benchmarks_helpers in linear_shared ~ name " : CHECK_PRINTABLE " ~ generator ( : fun rng_state -> let open Base_samplers in let string = readable_ascii_string rng_state ~ size { : min = 1 ; max = 1024 } in ( string , { Shared_linear . bytes = String . length string } ) ) ~ make_bench ( : fun generator ( ) -> let ( generated , workload ) = generator ( ) in let closure ( ) = ignore ( check_printable_ascii generated ( String . length generated - 1 ) ) in Generator . Plain { workload ; closure } )
let ( ) = Registration_helpers . register check_printable_benchmark
module Merge_types : Benchmark . S = struct type config = { max_size : int } let config_encoding = let open Data_encoding in conv ( fun { max_size } -> max_size ) ( fun max_size -> { max_size } ) ( obj1 ( req " max_size " int31 ) ) let default_config = { max_size = 64 } type workload = Merge_types_workload of { nodes : int ; consumed : Size . t } let workload_encoding = let open Data_encoding in conv ( function Merge_types_workload { nodes ; consumed } -> ( nodes , consumed ) ) ( fun ( nodes , consumed ) -> Merge_types_workload { nodes ; consumed } ) ( obj2 ( req " nodes " int31 ) ( req " consumed " int31 ) ) let workload_to_vector = function \| Merge_types_workload { nodes ; consumed } -> Sparse_vec . String . of_list [ ( " nodes " , float_of_int nodes ) ; ( " consumed " , float_of_int consumed ) ] let name = " MERGE_TYPES " let info = " Benchmarking merging of types " let tags = [ Tags . translator ] let intercept_var = Free_variable . of_string ( Format . asprintf " % s_const " name ) let coeff_var = Free_variable . of_string ( Format . asprintf " % s_coeff " name ) let size_model = Model . make ~ conv ( : function Merge_types_workload { nodes ; _ } -> ( nodes , ( ) ) ) ~ model : ( Model . affine_split_const ~ intercept1 : Builtin_benchmarks . timer_variable ~ intercept2 : intercept_var ~ coeff : coeff_var ) let codegen_model = Model . make ~ conv ( : function Merge_types_workload { nodes ; _ } -> ( nodes , ( ) ) ) ~ model ( : Model . affine ~ intercept : intercept_var ~ coeff : coeff_var ) let ( ) = Registration_helpers . register_for_codegen name ( Model . For_codegen codegen_model ) let models = [ ( " size_translator_model " , size_model ) ; ( " codegen " , codegen_model ) ] let merge_type_benchmark rng_state nodes ( ty : Script_ir_translator . ex_ty ) = let open Error_monad in Lwt_main . run ( Execution_context . make ~ rng_state >>=? fun ( ctxt , _ ) -> let ctxt = Gas_helpers . set_limit ctxt in match ty with \| Ex_ty ty -> let dummy_loc = 0 in Lwt . return ( Script_ir_translator . ty_eq ctxt dummy_loc ty ty ) >\|= Environment . wrap_tzresult >>=? fun ( _ , ctxt ' ) -> let consumed = Alpha_context . Gas . consumed ~ since : ctxt ~ until : ctxt ' in let workload = Merge_types_workload { nodes ; consumed = Z . to_int ( Gas_helpers . fp_to_z consumed ) } in let closure ( ) = ignore ( Script_ir_translator . ty_eq ctxt 0 ty ty ) in return ( Generator . Plain { workload ; closure } ) ) \|> function \| Ok closure -> closure \| Error errs -> global_error name errs let make_bench rng_state ( cfg : config ) ( ) = let nodes = Base_samplers . ( sample_in_interval ~ range { : min = 1 ; max = cfg . max_size } rng_state ) in let ty = Michelson_generation . Samplers . Random_type . m_type ~ size : nodes rng_state in merge_type_benchmark rng_state nodes ty let create_benchmarks ~ rng_state ~ bench_num config = List . repeat bench_num ( make_bench rng_state config ) end
let ( ) = Registration_helpers . register ( module Merge_types )
let rec dummy_type_generator size = let open Script_ir_translator in let open Script_typed_ir in if size <= 1 then Ex_ty unit_t else match dummy_type_generator ( size - 2 ) with \| Ex_ty r -> let l = unit_t in Ex_ty ( match pair_t ( - 1 ) l r with Error _ -> assert false \| Ok t -> t )
let rec dummy_comparable_type_generator size = let open Script_ir_translator in let open Script_typed_ir in if size <= 0 then Ex_comparable_ty unit_key else match dummy_comparable_type_generator ( size - 2 ) with \| Ex_comparable_ty r -> let l = unit_key in Ex_comparable_ty ( match pair_key ( - 1 ) l r with Error _ -> assert false \| Ok t -> t )
module Parse_type_shared = struct type config = { max_size : int } let default_config = { max_size = Constants_repr . michelson_maximum_type_size } let config_encoding = let open Data_encoding in conv ( fun { max_size } -> max_size ) ( fun max_size -> { max_size } ) ( obj1 ( req " max_size " int31 ) ) type workload = Type_workload of { nodes : int ; consumed : Size . t } let workload_encoding = let open Data_encoding in conv ( function Type_workload { nodes ; consumed } -> ( nodes , consumed ) ) ( fun ( nodes , consumed ) -> Type_workload { nodes ; consumed } ) ( obj2 ( req " nodes " int31 ) ( req " consumed " int31 ) ) let workload_to_vector = function \| Type_workload { nodes ; consumed } -> Sparse_vec . String . of_list [ ( " nodes " , float_of_int nodes ) ; ( " consumed " , float_of_int consumed ) ] let tags = [ Tags . translator ] end
let parse_ty ctxt node = Script_ir_translator . parse_ty ctxt ~ legacy : true ~ allow_lazy_storage : true ~ allow_operation : true ~ allow_contract : true ~ allow_ticket : true node
let unparse_ty ctxt ty = Script_ir_translator . unparse_ty ~ loc ( :- 1 ) ctxt ty
module Parse_type_benchmark : Benchmark . S = struct include Parse_type_shared let name = " PARSE_TYPE " let info = " Benchmarking parse_ty " let make_bench rng_state config ( ) = let open Error_monad in ( Lwt_main . run ( Execution_context . make ~ rng_state ) >>? fun ( ctxt , _ ) -> let ctxt = Gas_helpers . set_limit ctxt in let size = Random . State . int rng_state config . max_size in let ty = dummy_type_generator size in match ty with \| Ex_ty ty -> Environment . wrap_tzresult @@ unparse_ty ctxt ty >>? fun ( unparsed , _ ) -> Environment . wrap_tzresult @@ parse_ty ctxt unparsed >>? fun ( _ , ctxt ' ) -> let consumed = Z . to_int ( Gas_helpers . fp_to_z ( Alpha_context . Gas . consumed ~ since : ctxt ~ until : ctxt ' ) ) in let nodes = let x = Script_typed_ir . ty_size ty in Saturation_repr . to_int @@ Script_typed_ir . Type_size . to_int x in let workload = Type_workload { nodes ; consumed } in let closure ( ) = ignore ( parse_ty ctxt unparsed ) in ok ( Generator . Plain { workload ; closure } ) ) \|> function \| Ok closure -> closure \| Error errs -> global_error name errs let size_model = Model . make ~ conv ( : function Type_workload { nodes ; consumed = _ } -> ( nodes , ( ) ) ) ~ model : ( Model . affine ~ intercept : ( Free_variable . of_string ( Format . asprintf " % s_const " name ) ) ~ coeff ( : Free_variable . of_string ( Format . asprintf " % s_coeff " name ) ) ) let models = [ ( " size_translator_model " , size_model ) ] let create_benchmarks ~ rng_state ~ bench_num config = List . repeat bench_num ( make_bench rng_state config ) end
let ( ) = Registration_helpers . register ( module Parse_type_benchmark )
module Unparse_type_benchmark : Benchmark . S = struct include Parse_type_shared let name = " UNPARSE_TYPE " let info = " Benchmarking unparse_ty " let make_bench rng_state config ( ) = let open Error_monad in ( Lwt_main . run ( Execution_context . make ~ rng_state ) >>? fun ( ctxt , _ ) -> let ctxt = Gas_helpers . set_limit ctxt in let size = Random . State . int rng_state config . max_size in let ty = dummy_type_generator size in match ty with \| Ex_ty ty -> Environment . wrap_tzresult @@ unparse_ty ctxt ty >>? fun ( _ , ctxt ' ) -> let consumed = Z . to_int ( Gas_helpers . fp_to_z ( Alpha_context . Gas . consumed ~ since : ctxt ~ until : ctxt ' ) ) in let nodes = let x = Script_typed_ir . ty_size ty in Saturation_repr . to_int @@ Script_typed_ir . Type_size . to_int x in let workload = Type_workload { nodes ; consumed } in let closure ( ) = ignore ( unparse_ty ctxt ty ) in ok ( Generator . Plain { workload ; closure } ) ) \|> function \| Ok closure -> closure \| Error errs -> global_error name errs let size_model = Model . make ~ conv ( : function Type_workload { nodes ; consumed = _ } -> ( nodes , ( ) ) ) ~ model : ( Model . affine ~ intercept : ( Free_variable . of_string ( Format . asprintf " % s_const " name ) ) ~ coeff ( : Free_variable . of_string ( Format . asprintf " % s_coeff " name ) ) ) let models = [ ( " size_translator_model " , size_model ) ] let create_benchmarks ~ rng_state ~ bench_num config = List . repeat bench_num ( make_bench rng_state config ) let ( ) = Registration_helpers . register_for_codegen name ( Model . For_codegen size_model ) end
let ( ) = Registration_helpers . register ( module Unparse_type_benchmark )
module Unparse_comparable_type_benchmark : Benchmark . S = struct include Parse_type_shared let name = " UNPARSE_COMPARABLE_TYPE " let info = " Benchmarking unparse_comparable_ty " let make_bench rng_state config ( ) = let open Error_monad in let res = Lwt_main . run ( Execution_context . make ~ rng_state ) >>? fun ( ctxt , _ ) -> let ctxt = Gas_helpers . set_limit ctxt in let size = Random . State . int rng_state config . max_size in let ty = dummy_comparable_type_generator size in let nodes = let ( Script_ir_translator . Ex_comparable_ty ty ) = ty in let x = Script_typed_ir . comparable_ty_size ty in Saturation_repr . to_int @@ Script_typed_ir . Type_size . to_int x in match ty with \| Ex_comparable_ty comp_ty -> Environment . wrap_tzresult @@ Script_ir_translator . unparse_comparable_ty ~ loc ( ) : ctxt comp_ty >>? fun ( _ , ctxt ' ) -> let consumed = Z . to_int ( Gas_helpers . fp_to_z ( Alpha_context . Gas . consumed ~ since : ctxt ~ until : ctxt ' ) ) in let workload = Type_workload { nodes ; consumed } in let closure ( ) = ignore ( Script_ir_translator . unparse_comparable_ty ~ loc ( ) : ctxt comp_ty ) in ok ( Generator . Plain { workload ; closure } ) in match res with \| Ok closure -> closure \| Error errs -> global_error name errs let size_model = Model . make ~ conv ( : function Type_workload { nodes ; consumed = _ } -> ( nodes , ( ) ) ) ~ model : ( Model . affine ~ intercept : ( Free_variable . of_string ( Format . asprintf " % s_const " name ) ) ~ coeff ( : Free_variable . of_string ( Format . asprintf " % s_coeff " name ) ) ) let ( ) = Registration_helpers . register_for_codegen name ( Model . For_codegen size_model ) let models = [ ( " size_translator_model " , size_model ) ] let create_benchmarks ~ rng_state ~ bench_num config = List . repeat bench_num ( make_bench rng_state config ) end
let ( ) = Registration_helpers . register ( module Unparse_comparable_type_benchmark )
let gas_full t_kind code_or_data = let name = Format . asprintf " % a_ % a " Translator_workload . pp_kind t_kind Translator_workload . pp_code_or_data code_or_data in let intercept = Free_variable . of_string ( Format . asprintf " % s_const " name ) in let coeff = Free_variable . of_string ( Format . asprintf " % s_coeff " name ) in Model . affine ~ intercept ~ coeff
let size_full t_kind code_or_data = let name = Format . asprintf " % a_ % a " Translator_workload . pp_kind t_kind Translator_workload . pp_code_or_data code_or_data in let coeff1 = Free_variable . of_string ( Format . asprintf " % s_traversal " name ) in let coeff2 = Free_variable . of_string ( Format . asprintf " % s_int_bytes " name ) in let coeff3 = Free_variable . of_string ( Format . asprintf " % s_string_bytes " name ) in Model . trilinear ~ coeff1 ~ coeff2 ~ coeff3
let gas_based_model t_kind code_or_data = Model . make ~ conv ( : function \| Translator_workload . Typechecker_workload { consumed ; _ } -> ( consumed , ( ) ) ) ~ model ( : gas_full t_kind code_or_data )
let size_based_model t_kind code_or_data = Model . make ~ conv ( : function \| Translator_workload . Typechecker_workload { micheline_size ; _ } -> ( match micheline_size with \| { traversal ; int_bytes ; string_bytes } -> ( traversal , ( int_bytes , ( string_bytes , ( ) ) ) ) ) ) ~ model ( : size_full t_kind code_or_data )
type kind = Parsing \| Unparsing
type code_or_data = Code \| Data
type t = \| Typechecker_workload of { t_kind : kind ; code_or_data : code_or_data ; micheline_size : Size . micheline_size ; consumed : Size . t ; }
let kind_encoding : kind Data_encoding . t = let open Data_encoding in def " kind_encoding " @@ string_enum [ ( " parsing " , Parsing ) ; ( " unparsing " , Unparsing ) ]
let code_or_data_encoding : code_or_data Data_encoding . t = let open Data_encoding in def " code_or_data_encoding " @@ string_enum [ ( " code " , Code ) ; ( " data " , Data ) ]
let encoding : t Data_encoding . t = let open Data_encoding in def " translator_trace_encoding " @@ conv ( function \| Typechecker_workload { t_kind ; code_or_data ; micheline_size ; consumed } -> ( t_kind , code_or_data , micheline_size , consumed ) ) ( fun ( t_kind , code_or_data , micheline_size , consumed ) -> Typechecker_workload { t_kind ; code_or_data ; micheline_size ; consumed } ) ( tup4 kind_encoding code_or_data_encoding Size . micheline_size_encoding Size . encoding )
let pp_kind fmtr ( kind : kind ) = match kind with \| Parsing -> Format . pp_print_string fmtr " Parsing " \| Unparsing -> Format . pp_print_string fmtr " Unparsing "
let pp_code_or_data fmtr ( x : code_or_data ) = match x with \| Code -> Format . pp_print_string fmtr " Code " \| Data -> Format . pp_print_string fmtr " Data "
let pp fmtr ( trace : t ) = match trace with \| Typechecker_workload { t_kind ; code_or_data ; micheline_size ; consumed } -> Format . fprintf fmtr " typechecker_trace { % a ; % a ; % a ; % a } " pp_kind t_kind pp_code_or_data code_or_data Size . pp_micheline_size micheline_size Size . pp consumed
let workload_to_sparse_vec ( trace : t ) = let ( name , { Size . traversal ; int_bytes ; string_bytes } , consumed ) = match trace with \| Typechecker_workload { t_kind ; code_or_data ; micheline_size ; consumed } -> let name = Format . asprintf " % a_ % a " pp_kind t_kind pp_code_or_data code_or_data in ( name , micheline_size , consumed ) in let n s = name ^ " _ " ^ s in let vars = [ ( n " traversal " , Size . to_float traversal ) ; ( n " int_bytes " , Size . to_float int_bytes ) ; ( n " string_bytes " , Size . to_float string_bytes ) ; ( n " gas " , Size . to_float consumed ) ; ] in Sparse_vec . String . of_list vars
let data_typechecker_workload ctxt t_kind micheline_node ex_ty = let open Protocol in match ex_ty with \| Script_ir_translator . Ex_ty ty -> let ctxt = Gas_helpers . set_limit ctxt in Lwt_main . run ( Script_ir_translator . parse_data ctxt ~ legacy : false ~ allow_forged : false ty micheline_node \|> Lwt . map Environment . wrap_tzresult >>= fun res -> match res with \| Ok ( _res , ctxt_after ) -> let micheline_size = Size . of_micheline micheline_node in let consumed = Alpha_context . Gas . consumed ~ since : ctxt ~ until : ctxt_after in let trace = Typechecker_workload { t_kind ; code_or_data = Data ; micheline_size ; consumed = Size . of_int ( Z . to_int ( Gas_helpers . fp_to_z consumed ) ) ; } in Lwt . return ( Some trace ) \| Error errors -> Michelson_v1_error_reporter . report_errors ~ details : true ~ show_source : true Format . err_formatter errors ; Format . eprintf " . " @ ; Lwt . return None )
let code_typechecker_workload ( ctxt : Protocol . Alpha_context . context ) ( t_kind : kind ) ( code : Protocol . Alpha_context . Script . node ) ( bef : Protocol . Script_ir_translator . ex_stack_ty ) = let open Protocol in let ctxt = Gas_helpers . set_limit ctxt in let ( Script_ir_translator . Ex_stack_ty stack_ty ) = bef in Lwt_main . run ( Script_ir_translator . parse_instr Script_tc_context . data ctxt ~ legacy : false code stack_ty \|> Lwt . map Environment . wrap_tzresult >>= fun res -> match res with \| Ok ( _res , ctxt_after ) -> let micheline_size = Size . of_micheline code in let consumed = Alpha_context . Gas . consumed ~ since : ctxt ~ until : ctxt_after in let trace = Typechecker_workload { t_kind ; code_or_data = Code ; micheline_size ; consumed = Size . of_int ( Z . to_int ( Gas_helpers . fp_to_z consumed ) ) ; } in Lwt . return ( Some trace ) \| Error errs -> Michelson_v1_error_reporter . report_errors ~ details : true ~ show_source : true Format . err_formatter errs ; Format . eprintf " . " @ ; Lwt . return None )
let is_inline_attribute = function \| { txt ( " = inline " " \| ocaml . inline " ) } -> true \| _ -> false
let is_inlined_attribute = function \| { txt ( " = inlined " " \| ocaml . inlined " ) } -> true \| { txt ( " = unrolled " " \| ocaml . unrolled " ) } when Config . flambda -> true \| _ -> false
let is_specialise_attribute = function \| { txt ( " = specialise " " \| ocaml . specialise " ) } when Config . flambda -> true \| _ -> false
let is_specialised_attribute = function \| { txt ( " = specialised " " \| ocaml . specialised " ) } when Config . flambda -> true \| _ -> false
let is_local_attribute = function \| { txt ( " = local " " \| ocaml . local " ) } -> true \| _ -> false
let find_attribute p attributes = let inline_attribute , other_attributes = List . partition ( fun a -> p a . Parsetree . attr_name ) attributes in let attr = match inline_attribute with \| [ ] -> None \| [ attr ] -> Some attr \| _ :: { Parsetree . attr_name = { txt ; loc } ; _ } :: _ -> Location . prerr_warning loc ( Warnings . Duplicated_attribute txt ) ; None in attr , other_attributes
let is_unrolled = function \| { txt " = unrolled " " \| ocaml . unrolled " } -> true \| { txt " = inline " " \| ocaml . inline " " \| inlined " " \| ocaml . inlined " } -> false \| _ -> assert false
let get_id_payload = let open Parsetree in function \| PStr [ ] -> Some " " \| PStr [ { pstr_desc = Pstr_eval ( { pexp_desc } , [ ] ) } ] -> begin match pexp_desc with \| Pexp_ident { txt = Longident . Lident id } -> Some id \| _ -> None end \| _ -> None
let parse_id_payload txt loc ~ default ~ empty cases payload = let [ @ local ] warn ( ) = let ( %> ) f g x = g ( f x ) in let msg = cases \|> List . map ( fst %> Printf . sprintf " ' % s ' " ) \|> String . concat " , " \|> Printf . sprintf " It must be either % s or empty " in Location . prerr_warning loc ( Warnings . Attribute_payload ( txt , msg ) ) ; default in match get_id_payload payload with \| Some " " -> empty \| None -> warn ( ) \| Some id -> match List . assoc_opt id cases with \| Some r -> r \| None -> warn ( )
let parse_inline_attribute attr = match attr with \| None -> Default_inline \| Some { Parsetree . attr_name = { txt ; loc } as id ; attr_payload = payload } -> let open Parsetree in if is_unrolled id then begin let warning txt = Warnings . Attribute_payload ( txt , " It must be an integer literal " ) in match payload with \| PStr [ { pstr_desc = Pstr_eval ( { pexp_desc } , [ ] ) } ] -> begin match pexp_desc with \| Pexp_constant ( Pconst_integer ( s , None ) ) -> begin try Unroll ( Misc . Int_literal_converter . int s ) with Failure _ -> Location . prerr_warning loc ( warning txt ) ; Default_inline end \| _ -> Location . prerr_warning loc ( warning txt ) ; Default_inline end \| _ -> Location . prerr_warning loc ( warning txt ) ; Default_inline end else parse_id_payload txt loc ~ default : Default_inline ~ empty : Always_inline [ " never " , Never_inline ; " always " , Always_inline ; ] payload
let parse_specialise_attribute attr = match attr with \| None -> Default_specialise \| Some { Parsetree . attr_name = { txt ; loc } ; attr_payload = payload } -> parse_id_payload txt loc ~ default : Default_specialise ~ empty : Always_specialise [ " never " , Never_specialise ; " always " , Always_specialise ; ] payload
let parse_local_attribute attr = match attr with \| None -> Default_local \| Some { Parsetree . attr_name = { txt ; loc } ; attr_payload = payload } -> parse_id_payload txt loc ~ default : Default_local ~ empty : Always_local [ " never " , Never_local ; " always " , Always_local ; " maybe " , Default_local ; ] payload
let get_inline_attribute l = let attr , _ = find_attribute is_inline_attribute l in parse_inline_attribute attr
let get_specialise_attribute l = let attr , _ = find_attribute is_specialise_attribute l in parse_specialise_attribute attr
let get_local_attribute l = let attr , _ = find_attribute is_local_attribute l in parse_local_attribute attr
let check_local_inline loc attr = match attr . local , attr . inline with \| Always_local , ( Always_inline \| Unroll _ ) -> Location . prerr_warning loc ( Warnings . Duplicated_attribute " local / inline " ) \| _ -> ( )
let add_inline_attribute expr loc attributes = match expr , get_inline_attribute attributes with \| expr , Default_inline -> expr \| Lfunction ( { attr = { stub = false } as attr } as funct ) , inline -> begin match attr . inline with \| Default_inline -> ( ) \| Always_inline \| Never_inline \| Unroll _ -> Location . prerr_warning loc ( Warnings . Duplicated_attribute " inline " ) end ; let attr = { attr with inline } in check_local_inline loc attr ; Lfunction { funct with attr = attr } \| expr , ( Always_inline \| Never_inline \| Unroll _ ) -> Location . prerr_warning loc ( Warnings . Misplaced_attribute " inline " ) ; expr

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