From: WANG Date: Wed, 14 Aug 2013 14:44:52 +0000 (+0200) Subject: Adding new source file faustio.ml, including class waveio and class csvio. X-Git-Url: https://scm.cri.ensmp.fr/git/Faustine.git/commitdiff_plain/a891a827a9bad83d44164ffdd7b28f070c439e46?hp=--cc Adding new source file faustio.ml, including class waveio and class csvio. --- a891a827a9bad83d44164ffdd7b28f070c439e46 diff --git a/interpretor/Makefile b/interpretor/Makefile index 6de2b12..23b74e4 100644 --- a/interpretor/Makefile +++ b/interpretor/Makefile @@ -2,11 +2,11 @@ # # The Caml sources (including camlyacc and camllex source files) -SOURCES = types.ml parser.mly lexer.mll basic.ml symbol.ml value.ml signal.ml beam.ml faustexp.ml interpreter.ml preprocess.ml main.ml preprocess_stubs.cpp +SOURCES = types.ml parser.mly lexer.mll basic.ml symbol.ml aux.ml value.ml signal.ml beam.ml process.ml faustio.ml preprocess.ml main.ml preprocess_stubs.cpp # The executable file to generate -EXEC = mrfausti +EXEC = faustine # Path to ocaml include header files export OCAML_INCLUDE_PATH diff --git a/interpretor/aux.ml b/interpretor/aux.ml new file mode 100644 index 0000000..3bc11a6 --- /dev/null +++ b/interpretor/aux.ml @@ -0,0 +1,21 @@ +(** + Module: Aux + Description: all auxiliary functions + @author WANG Haisheng + Created: 12/08/2013 Modified: 13/08/2013 +*) + + + +let array_map2 = fun f -> fun a -> fun b -> + let n1 = Array.length a in + let n2 = Array.length b in + if n1 = n2 then Array.init n1 (fun i -> f a.(i) b.(i)) + else raise (Invalid_argument "Array.map2 size not matched.");; + +let array_map3 = fun f -> fun a -> fun b -> fun c -> + let n1 = Array.length a in + let n2 = Array.length b in + let n3 = Array.length c in + if n1 = n2 && n1 = n3 then Array.init n1 (fun i -> f a.(i) b.(i) c.(i)) + else raise (Invalid_argument "Array.map2 size not matched.");; diff --git a/interpretor/faustio.ml b/interpretor/faustio.ml new file mode 100644 index 0000000..b05f18d --- /dev/null +++ b/interpretor/faustio.ml @@ -0,0 +1,163 @@ +(** + Module: Faustio + Description: audio input/output, csv input/output + @author WANG Haisheng + Created: 12/08/2013 Modified: 13/08/2013 +*) + +open Types;; +open Beam;; +open Aux;; + +let default_output_path = "../output_sounds/";; + +class virtual io = + object + method virtual read : string array -> beam + method virtual write : int array -> value_type array array -> string array + method private to_float : value_type array array -> float array array = + fun (origin : value_type array array) -> + let data = + let value2float = fun (v : value_type) -> v#to_float_array in + Array.map (Array.map value2float) origin in + Array.map Array.concat (Array.map Array.to_list data) + end;; + +class waveio : io_type = + object (self) + inherit io + method read : string array -> beam = + fun (paths : string array) -> + let n = Array.length paths in + if n = 0 then + new beam [||] + else + let signals = + let files = Array.map Sndfile.openfile paths in + let frames = Array.map Int64.to_int (Array.map Sndfile.frames files) in + let rates = Array.map Sndfile.samplerate files in + let create_container = fun l -> Array.create l 1. in + let containers = Array.map create_container frames in + let _ = array_map2 Sndfile.read files containers in + let _ = Array.map Sndfile.close files in + array_map2 (new signal) rates containers in + new beam signals + + method write : int array -> value_type array array -> string array = + fun (rates : int array) -> + fun (output : value_type array array) -> + let () = print_string(" Faustine -> Writing wave files...") in + let tic = Sys.time () in + + let n = Array.length output in + let paths = Array.init n (fun i -> + default_output_path ^ "output" ^ (string_of_int i) ^ ".wav") in + + let files = + let channels = + let get_channel = fun l -> fun s -> + match s.(l - 1)#get with + | Vec vec -> vec#size + | _ -> 1 in + Array.map (get_channel n) output in + let format = Sndfile.format Sndfile.MAJOR_WAV Sndfile.MINOR_PCM_16 in + let openwr = fun path -> fun channel -> fun rate -> + Sndfile.openfile ~info:(Sndfile.RDWR, format, channel, rate) path in + array_map3 openwr paths channels rates in + + let () = + let data = self#to_float output in + let _ = array_map2 Sndfile.write files data in + let _ = Array.map Sndfile.close files in + let toc = Sys.time () in + let duration = toc -. tic in + Print_endline + (" Done. (duration: " ^ (string_of_float duration) ^ "s)") in + paths + end;; + +(* +class csvio : io_type = + object (self) + inherit io + method private csvread = + method read : string array -> beam = + + + + method write : value_type array array -> string array + end;; +*) + +let csvread = fun (ic : in_channel) -> + let string_list = ref [] in + try + while true do + string_list := !string_list @ [(input_line ic)] + done; + [||] + with End_of_file -> + (*let () = print_endline(List.nth !string_list 0) in*) + Array.of_list (List.map float_of_string !string_list);; + +let read_input_csv = fun argv -> + let n_input = (Array.length argv) - 4 in + if n_input < 0 then + raise Missing_Expression + else if n_input = 0 then + ([], []) + else + (* open csv file *) + let file_string_array = Array.sub argv 4 n_input in + let make_chemin s = io_macro_to_string Input_Route_string ^ s in + let file_chemin_string_array = Array.map make_chemin file_string_array in + let file_array = Array.map open_in file_chemin_string_array in + let file_list = Array.to_list file_array in + + (* read sample rates and data *) + let rate_list = Array.to_list (Array.create n_input 0) in + let data_float_array_list = List.map csvread file_list in + let _ = List.map close_in file_list in + (rate_list, data_float_array_list);; + + +let write_output_csv = fun channel_int_list -> fun data_float_array_list -> + let () = print_string(" Faustine -> Writing csv files...") in + let tic = Sys.time () in + + (* make output txt file names : output0, output1, ... *) + let n_output = List.length data_float_array_list in + let n_array = Array.init n_output (fun n -> n) in + let make_file_name i = "output" ^ (string_of_int i) ^ ".csv" in + + (* make output wave file routes *) + let make_chemin s = io_macro_to_string Output_Route_string ^ s in + let file_name_string_array = Array.map make_file_name n_array in + let file_chemin_string_array = Array.map make_chemin file_name_string_array in + let file_chemin_string_list = Array.to_list file_chemin_string_array in + + (* open output channels *) + let file_list = List.map open_out file_chemin_string_list in + let data_string_array_list = List.map (Array.map string_of_float) data_float_array_list in + let array_to_string = fun data_string_array -> fun channel_int -> + let data_length = Array.length data_string_array in + let rec to_string_rec = + fun data -> fun channel -> fun n -> fun i -> fun column -> + if i < n then + ( + let element = data.(i) in + if column < (channel - 1) then + element ^ "," ^ (to_string_rec data channel n (i + 1) (column + 1)) + else if column = (channel - 1) then + element ^ "\n" ^ (to_string_rec data channel n (i + 1) 0) + else raise (Invalid_argument "write_output_txt.") + ) + else "" in + to_string_rec data_string_array channel_int data_length 0 0 in + + let data_string_list = List.map2 array_to_string data_string_array_list channel_int_list in + let _ = List.map2 output_string file_list data_string_list in + let _ = List.map close_out file_list in + let toc = Sys.time () in + print_endline(" Done. (duration: " ^ (string_of_float (toc -. tic)) ^ "s)");; + diff --git a/interpretor/interpreter.ml b/interpretor/interpreter.ml deleted file mode 100644 index 226fadf..0000000 --- a/interpretor/interpreter.ml +++ /dev/null @@ -1,498 +0,0 @@ -(** - Module: Interpreter - Description: input beam -> process -> output beam - @author WANG Haisheng - Created: 15/05/2013 Modified: 04/06/2013 -*) - -open Types;; -open Value;; -open Signal;; -open Faustexp;; - -(* EXCEPTIONS *) - -(** Exception raised during interpretation of faust process.*) -exception Evaluation_Error of string;; - - - -(* MACRO *) - -(** Macro constants of this file.*) -type interpreter_macro = - | Number_samples_int - | Max_Eval_Time_int;; - -(** val interpreter_macro_to_value : returns the value associated with the macro.*) -let interpreter_macro_to_value m = match m with - | Number_samples_int -> 0xFFFFF - | Max_Eval_Time_int -> 0xFFFFFFFF;; - - -(* OUTPUT WAVE COMPUTATION *) - -(** val func_of_func_array : (int -> value) array -> (int -> value array), -applies the same int parameter to each element of function array, -produces a value array.*) -let fun_array_to_fun = fun fun_array -> - let reverse = fun t -> fun f -> f t in - let new_fun = fun t-> Array.map (reverse t) fun_array in - new_fun;; - - -(** val computing : (int -> value array) -> int -> int -> float array array array, -applies time sequence "0,1,2,3,...,max" to signal beam, -returns primitive output data.*) -let computing = fun f -> fun width -> fun length -> - let container_float_array_array_array = - ref (Array.make length (Array.make width [||])) in - let index = ref 0 in - - try - while !index < length do - (!container_float_array_array_array).(!index) - <- (Array.map convert_back_R (f (!index))); - incr index; - done; - !container_float_array_array_array - - with x -> - let error_message = - match x with - |Convert_Error s -> "Convert_Error: " ^ s - |Value_operation s -> "Value_operation: " ^ s - |Signal_operation s -> "Signal_operation: " ^ s - |Beam_Matching_Error s -> "Beam_Matching_Error: " ^ s - |Evaluation_Error s -> "Evaluation_Error: " ^ s - |NotYetDone -> "NotYetDone" - |_ -> "Compute finished." - in - let () = print_endline error_message in - Array.sub (!container_float_array_array_array) 0 !index;; - - -(** val matrix_transpose : 'a array array -> 'a array array, -transposes the input matrix.*) -let matrix_transpose = fun m_array_array -> fun width -> - let get_element = fun i -> fun array -> Array.get array i in - let get_line = fun array_array -> fun i -> - Array.map (get_element i) array_array in - let transpose array_array = Array.init width (get_line array_array) in - transpose m_array_array;; - - -(** val channels : 'a array array array -> int -> int array, -returns an array of number of channels. *) -let channels = fun f_array_array_array -> fun width -> - let channel = fun faaa -> fun i -> - let faa = faaa.(i) in - let length = Array.length faa in - let fa = faa.(length - 1) in - Array.length fa - in - let channel_array = Array.init width (channel f_array_array_array) in - channel_array;; - - -(** val arrange : 'a array array array -> int -> 'a array list, -arranges the output data in "array list" form. *) -let arrange = fun float_array_array_array -> fun width -> - let concat faaa = fun i -> - let faa = faaa.(i) in - Array.concat (Array.to_list faa) - in - let float_array_array = Array.init width (concat float_array_array_array) in - let float_array_list = Array.to_list float_array_array in - float_array_list;; - - -(** val compute : (int -> value) list -> (int list) * (float array list). -input: a list of signal functions -output: channel number list, data list.*) -let compute fun_list = - let () = print_endline("Computing output signals...") in - - (* arrange input information *) - let length = interpreter_macro_to_value Number_samples_int in - let width = List.length fun_list in - let beam_fun = fun_array_to_fun (Array.of_list fun_list) in - - (* calculate output wave *) - let tmp_float_array_array_array = computing beam_fun width length in - - (* arrange output data *) - let output_float_array_array_array = matrix_transpose tmp_float_array_array_array width in - let channel_array = channels output_float_array_array_array width in - let channel_list = Array.to_list channel_array in - let output_float_array_list = arrange output_float_array_array_array width in - (channel_list, output_float_array_list);; - - - -(* INTERPRETATION *) - -(** val sublist : 'a list -> int -> int -> 'a list, -[sublist l start length], returns the sublist of list 'l', -from index 'start', with length 'length'.*) -let sublist l start length = - try - let arr = Array.of_list l in - let sub_array = Array.sub arr start length in - Array.to_list sub_array - - with (Invalid_argument "Array.sub") -> - raise (Invalid_argument "List.sub");; - - -(** val make_beam : (int list) * (float array list) -> (int * (int -> value)) list, -input: (sample rate list, data list) -output: beam = (sample rate, function) list *) -let make_beam = fun input -> - let rate_list = fst input in - let float_array_list = snd input in - let value_array_list = - List.map (Array.map return_R) float_array_list in - let fun_list = List.map Array.get value_array_list in - let make_signal = fun rate -> fun f -> (rate, f) in - let beam = List.map2 make_signal rate_list fun_list in - beam;; - - -(** val interpret_const : value -> beam -> beam, generates constant signal with frequency 0. *) -let interpret_const = fun v -> fun input_beam -> - let n = List.length input_beam in - if n = 0 then [(0,(fun t -> v))] - else raise (Evaluation_Error "Const");; - - -(** val interpret_ident : string -> beam -> beam, -generates signals according to identified symbols. *) -let interpret_ident = fun s -> fun input_beam -> - let n = List.length input_beam in - match s with - |Pass -> if n = 1 then input_beam else raise (Evaluation_Error "Ident _") - - |Stop -> if n = 1 then [] else raise (Evaluation_Error "Ident !") - - |Add -> if n = 2 then [signal_add (List.nth input_beam 0) (List.nth input_beam 1)] - else raise (Evaluation_Error "Ident +") - - |Sup -> if n = 2 then [signal_sub (List.nth input_beam 0) (List.nth input_beam 1)] - else raise (Evaluation_Error "Ident -") - - |Mul -> if n = 2 then [signal_mul (List.nth input_beam 0) (List.nth input_beam 1)] - else raise (Evaluation_Error "Ident *") - - |Div -> if n = 2 then [signal_div (List.nth input_beam 0) (List.nth input_beam 1)] - else raise (Evaluation_Error "Ident /") - - |Delay -> if n = 2 then [signal_delay (List.nth input_beam 0) (List.nth input_beam 1)] - else raise (Evaluation_Error "Ident @") - - |Mem -> if n = 1 then [signal_mem (List.nth input_beam 0)] - else raise (Evaluation_Error "Ident mem") - - |Vectorize -> if n = 2 then [signal_vectorize (List.nth input_beam 0) (List.nth input_beam 1)] - else raise (Evaluation_Error "Ident vectorize") - - |Serialize -> if n = 1 then [signal_serialize (List.nth input_beam 0)] - else raise (Evaluation_Error "Ident serialize") - - |Concat -> if n = 2 then [signal_append (List.nth input_beam 0) (List.nth input_beam 1)] - else raise (Evaluation_Error "Ident #") - - |Nth -> if n = 2 then [signal_nth (List.nth input_beam 0) (List.nth input_beam 1)] - else raise (Evaluation_Error "Ident []") - - |Floor -> if n = 1 then [signal_floor (List.nth input_beam 0)] - else raise (Evaluation_Error "Ident floor") - - |Int -> if n = 1 then [signal_int (List.nth input_beam 0)] - else raise (Evaluation_Error "Ident int") - - |Sin -> if n = 1 then [signal_sin (List.nth input_beam 0)] - else raise (Evaluation_Error "Ident sin") - - |Rdtable -> if n = 3 then [signal_rdtable (List.nth input_beam 0) - (List.nth input_beam 1) (List.nth input_beam 2)] - else raise (Evaluation_Error "Ident rdtable") - - |Selecttwo -> if n = 3 then [signal_select2 (List.nth input_beam 0) (List.nth input_beam 1) - (List.nth input_beam 2)] - else raise (Evaluation_Error "Ident select2") - - |Selectthree -> if n = 4 then [signal_select3 (List.nth input_beam 0) (List.nth input_beam 1) - (List.nth input_beam 2) (List.nth input_beam 3)] - else raise (Evaluation_Error "Ident select3") - - |Prefix -> if n = 2 then [signal_prefix (List.nth input_beam 0) (List.nth input_beam 1)] - else raise (Evaluation_Error "Ident prefix") - - |Mod -> if n = 2 then [signal_mod (List.nth input_beam 0) (List.nth input_beam 1)] - else raise (Evaluation_Error "Ident %") - - |Larger -> if n = 2 then [signal_sup (List.nth input_beam 0) (List.nth input_beam 1)] - else raise (Evaluation_Error "Ident >") - - |Smaller -> if n = 2 then [signal_inf (List.nth input_beam 0) (List.nth input_beam 1)] - else raise (Evaluation_Error "Ident <");; - - - -(** val rec eval : faust_exp -> beam -> beam, -main interpretation work is done here. *) -let rec eval exp_faust dimension_tree input_beam = - - -(** val interpret_par : faust_exp -> faust_exp -> beam -> beam, -interprets par(e1, e2) with input beam, produces output beam.*) -let interpret_par = fun e1 -> fun e2 -> fun dimension_tree -> fun input_beam -> - - (* dimension information *) - let n = List.length input_beam in - let subtree1 = subtree_left dimension_tree in - let subtree2 = subtree_right dimension_tree in - let d1 = get_root subtree1 in - let d2 = get_root subtree2 in - - if n = (fst d1) + (fst d2) then - ( - (* segmentation of input beam *) - let input_beam1 = sublist input_beam 0 (fst d1) in - let input_beam2 = sublist input_beam (fst d1) (fst d2) in - - (* evaluate two expressions respectively *) - let output_beam1 = eval e1 subtree1 input_beam1 in - let output_beam2 = eval e2 subtree2 input_beam2 in - - (* concat two output beams *) - if List.length output_beam1 = snd d1 && List.length output_beam2 = snd d2 - then (output_beam1 @ output_beam2) - else raise (Evaluation_Error "Par") - ) - else raise (Evaluation_Error "Par") in - - -(** val interpret_seq : faust_exp -> faust_exp -> beam -> beam, -interprets seq(e1, e2) with input beam, produces output beam.*) -let interpret_seq = fun e1 -> fun e2 -> fun dimension_tree -> fun input_beam -> - - (* dimension information *) - let n = List.length input_beam in - let subtree1 = subtree_left dimension_tree in - let subtree2 = subtree_right dimension_tree in - let d1 = get_root subtree1 in - let d2 = get_root subtree2 in - - - if n = fst d1 then - ( - (* evaluate the first expression *) - let output_beam1 = eval e1 subtree1 input_beam in - - (* evaluate the second expression *) - if List.length output_beam1 = fst d2 - then eval e2 subtree2 output_beam1 - else raise (Evaluation_Error "Seq") - ) - else raise (Evaluation_Error "Seq") in - - -(** val interpret_split : faust_exp -> faust_exp -> beam -> beam, -interprets split(e1, e2) with input beam, produces output beam.*) -let interpret_split = fun e1 -> fun e2 -> fun dimension_tree -> fun input_beam -> - - (* dimension information *) - let n = List.length input_beam in - let subtree1 = subtree_left dimension_tree in - let subtree2 = subtree_right dimension_tree in - let d1 = get_root subtree1 in - let d2 = get_root subtree2 in - - - if n = fst d1 then - ( - (* evaluate the first expression *) - let output_beam1 = eval e1 subtree1 input_beam in - - (* beam matching *) - let ref_output_beam1 = ref (beam_add_one_memory output_beam1) in - let input_beam2 = List.concat - (Array.to_list (Array.make ((fst d2)/(List.length output_beam1)) !ref_output_beam1)) - in - - (* evaluate the second expression *) - if List.length input_beam2 = fst d2 - then eval e2 subtree2 input_beam2 - else raise (Evaluation_Error "Split") - ) - else raise (Evaluation_Error "Split") in - - -(** val interpret_merge : faust_exp -> faust_exp -> beam -> beam, -interprets merge(e1, e2) with input beam, produces output beam.*) -let interpret_merge = fun e1 -> fun e2 -> fun dimension_tree -> fun input_beam -> - - (* dimension information *) - let n = List.length input_beam in - let subtree1 = subtree_left dimension_tree in - let subtree2 = subtree_right dimension_tree in - let d1 = get_root subtree1 in - let d2 = get_root subtree2 in - - - if n = fst d1 then - ( - (* evaluate the first expression *) - let output_beam1 = eval e1 subtree1 input_beam in - - (* beam matching *) - let input_beam2 = - ( - let fois = (snd d1)/(fst d2) in - let ref_beam = ref (sublist output_beam1 0 (fst d2)) in - for i = 1 to fois - 1 do - let temp_beam = sublist output_beam1 (i*(fst d2)) (fst d2) in - ref_beam := List.map2 signal_add (!ref_beam) temp_beam; - done; - !ref_beam - ) - in - - (* evaluate the second expression *) - if List.length input_beam2 = fst d2 - then eval e2 subtree2 input_beam2 - else raise (Evaluation_Error "Merge") - ) - else raise (Evaluation_Error "Merge") in - - -(** val interpret_rec : faust_exp -> faust_exp -> beam -> beam, -interprets rec(e1, e2) with input beam, produces output beam.*) -let interpret_rec = fun e1 -> fun e2 -> fun dimension_tree -> fun input_beam -> - - (* dimension information *) - let subtree1 = subtree_left dimension_tree in - let subtree2 = subtree_right dimension_tree in - let d1 = get_root subtree1 in - let d2 = get_root subtree2 in - - (* estimate stockage size for delay *) - let delay_int = 1 + delay e2 + delay e1 in - - (* prepare stockage *) - let memory_hashtbl = Hashtbl.create delay_int in - let rate_list = ref (Array.to_list (Array.make (snd d1) 0)) in - - (** val apply_to : 'a -> ('a -> 'b) -> 'b *) - let apply_to = fun t -> fun f -> f t in - - (** val get_value_fun_list : (int -> (int list) * (value list)) -> (int -> value) list *) - let get_value_fun_list = fun beam_fun -> - let tmp = fun beam_fun -> fun i -> fun t -> - List.nth (snd (beam_fun t)) i in - List.map (tmp beam_fun) (Array.to_list (Array.init (snd d1) (fun n -> n))) in - - (** val make_signal : int -> (int -> value) -> signal, combines rate and function. *) - let make_signal = fun rate -> fun f -> (rate, f) in - - (** val output_beam_fun : int -> (int list) * (value list), with - input : time - output: rate list * value list *) - let rec output_beam_fun = fun t -> - - (* initial value in constrctor "rec '~'" *) - if t < 0 then - let init_rate_list = Array.to_list (Array.make (snd d1) 0) in - let value_list = Array.to_list (Array.make (snd d1) Zero) in - (init_rate_list, value_list) - - (* check stockage at time t *) - else if Hashtbl.mem memory_hashtbl t then - (!rate_list, Hashtbl.find memory_hashtbl t) - - (* blocks : "a ~ b", calculate rate list and value list at time t *) - else - (* mid_output_fun_list : (int -> value) list *) - let mid_output_fun_list = get_value_fun_list output_beam_fun in - - (* b_input_fun_list : (int -> value) list *) - let b_input_fun_list = List.map - (fun s -> fun t -> s (t - 1)) - (sublist mid_output_fun_list 0 (fst d2)) in - - (* b_input_beam : signal list *) - let b_input_beam = List.map2 make_signal - (sublist !rate_list 0 (fst d2)) - b_input_fun_list in - - (* evaluation of block "b" *) - let b_output_beam = (eval e2 subtree2 b_input_beam) in - - (* evaluation of block "a" *) - let a_input_beam = b_output_beam @ input_beam in - let mid_output_beam = eval e1 subtree1 a_input_beam in - - (* calculate rate list and value list at time t *) - let mid_output_rate_list = List.map fst mid_output_beam in - let mid_output_value_list = List.map (apply_to t) (List.map snd mid_output_beam) in - - (* update stockage *) - let () = (rate_list := mid_output_rate_list) in - let () = Hashtbl.add memory_hashtbl t mid_output_value_list in - let () = Hashtbl.remove memory_hashtbl (t - delay_int) in - (mid_output_rate_list, mid_output_value_list) in - - (* output_beam : signal list *) - let output_beam = List.map2 make_signal !rate_list (get_value_fun_list output_beam_fun) in - output_beam in - - - (** Call for previous functions *) - match exp_faust with - |Const v -> interpret_const v input_beam - |Ident s -> interpret_ident s input_beam - |Par (e1, e2) -> interpret_par e1 e2 dimension_tree input_beam - |Seq (e1, e2) -> interpret_seq e1 e2 dimension_tree input_beam - |Split (e1, e2) -> interpret_split e1 e2 dimension_tree input_beam - |Merge (e1, e2) -> interpret_merge e1 e2 dimension_tree input_beam - |Rec (e1, e2) -> interpret_rec e1 e2 dimension_tree input_beam;; - - -(** val extract_rate : (int * (int -> value)) list -> int list, -gets the sample rate list from beam.*) -let extract_rate = fun beam -> - let rate_naive_list = List.map fst beam in - let correct_rate r = - if r = 0 then 44100 - else if r > 0 then r - else raise (Evaluation_Error "Rec2") - in - let rate_list = List.map correct_rate rate_naive_list in - rate_list;; - - -(** val interpreter : faust_exp -> (int list) * (float array list) -> -(int list) * (int list) * (float array list) -input: faust expression, sample rate list * input data list -output: channel list * sample rate list * output data list.*) -let interpreter exp_faust input = - let () = print_endline("Interpretation...") in - - (* make input beam *) - let input_beam = make_beam input in - - (* estimate process dimension *) - let dimension_tree = dim exp_faust in - - (* interprete output beam *) - let output_beam = eval exp_faust dimension_tree input_beam in - - (* get rate list from output beam *) - let rate_list = extract_rate output_beam in - - (* get channel list and data list from output beam *) - let (channel_list, float_array_list) = compute (List.map snd output_beam) in - (channel_list, rate_list, float_array_list);; - diff --git a/interpretor/main.ml b/interpretor/main.ml index b703a72..54b7265 100644 --- a/interpretor/main.ml +++ b/interpretor/main.ml @@ -28,7 +28,7 @@ let io_macro_to_string m = match m with | Input_Route_string -> "" | Output_Route_string -> "../output_sounds/" | Dsp_Route_string -> "";; - + (** val set_GC : unit -> unit *) let set_GC () = diff --git a/interpretor/faustexp.ml b/interpretor/process.ml similarity index 96% rename from interpretor/faustexp.ml rename to interpretor/process.ml index e8ff318..31cc6c9 100644 --- a/interpretor/faustexp.ml +++ b/interpretor/process.ml @@ -1,11 +1,12 @@ (** - Module: Faustexp - Description: Faust expression evaluation + Module: Process + Description: Faust process classes @author WANG Haisheng - Created: 03/06/2013 Modified: 04/08/2013 + Created: 03/06/2013 Modified: 14/08/2013 *) open Types;; +open Aux;; open Basic;; open Symbol;; open Value;; @@ -269,12 +270,6 @@ and proc_rec : faust_exp -> process_type = (beam_func t).(i) in Array.init self#dim#output (get_signal beam_at) in - let array_map2 = fun f -> fun a -> fun b -> - let n1 = Array.length a in - let n2 = Array.length b in - if n1 = n2 then Array.init n1 (fun i -> f a.(i) b.(i)) - else raise (Process_error "Array.map2 size not matched.") in - let feedback : (time -> value_type array) -> beam = fun beam_at -> let signals_at = split beam_at in diff --git a/interpretor/types.ml b/interpretor/types.ml index a252ed9..3d14095 100644 --- a/interpretor/types.ml +++ b/interpretor/types.ml @@ -148,3 +148,10 @@ class type process_type = method delay : int method eval : beam_type -> beam_type end;; + + +class type io_type = + object + method read : string array -> beam_type + method write : value_type array array -> string array + end;;