Initial import.

[Faustine.git] / interpretor / signal.ml

(**
        Module: Signal  
        Description: type signal = rate * (int -> value), operations of signals.
        @author WANG Haisheng   
        Created: 03/06/2013     Modified: 03/06/2013
*)

open Types;;
open Value;;

(* EXCEPTIONS *)

(** Exception raised in operations of signals.*)
exception Signal_operation of string;;



(* MACRO *)

(** Macro constants of the file.*)
type signal_macro = Delay_Memory_Length_int;;


(** val signal_macro_to_int : signal_macro -> int.*)
let signal_macro_to_int m = match m with
                                 |Delay_Memory_Length_int -> 10000;;


(* SIGNAL OPERATIONS *)

(** val frequency : signal -> int, returns the frequency of a signal.*)
let frequency s = fst s;;


(** val signal_fun : signal -> (int -> value), returns the functional part of a signal.*)
let signal_fun s = snd s;;


(** val check_frequency : int -> int -> int, returns the correction of frequency.*)
let check_frequency = fun f1 -> fun f2 ->
        if f1 = f2 || f2 = 0 then f1
        else if f1 = 0 then f2
        else raise (Signal_operation "frequency not matched.");;

(** val signal_check_frequency : signal -> signal -> int, 
checks the frequencies of two input signals, and returns common frequency or raise an exception.*)
let signal_check_frequency = fun s1 -> fun s2 ->
        let f1 = frequency s1 in
        let f2 = frequency s2 in
        check_frequency f1 f2;;


(** val signal_check_frequency3 : signal -> signal -> signal -> int,
checks the frequencies of three input signal, and returns common frequency or raise an exception.*)
let signal_check_frequency3 = fun s1 -> fun s2 -> fun s3 ->
        let f1 = signal_check_frequency s1 s2 in
        let f2 = signal_check_frequency s1 s3 in
        check_frequency f1 f2;;


(** val signal_check_frequency4 : signal -> signal -> signal -> signal -> int,
checks the frequencies of three input signal, and returns common frequency or raise an exception.*)
let signal_check_frequency4 = fun s1 -> fun s2 -> fun s3 -> fun s4 ->
        let f1 = signal_check_frequency s1 s2 in
        let f2 = signal_check_frequency s3 s4 in
        check_frequency f1 f2;;


(** val signal_add_one_memory : signal -> signal, 
returns the signal with memory of one latest sample.*)
let signal_add_one_memory = fun s ->
        let new_signal = factory_add_memory (signal_fun s) 1 in
            (frequency s, new_signal);;


(** val beam_add_one_memory : signal list -> signal list,
adds memory of one latest sample for each element in signal list.*)
let beam_add_one_memory = fun beam -> 
        List.map signal_add_one_memory beam;;


(** val signal_add : signal -> signal -> signal, output(t) = input1(t) + input2(t), 
    frequency consistent.*)
let signal_add s1 s2 = 
        let f = signal_check_frequency s1 s2 in
        let new_signal = fun t -> ((signal_fun s1) t) +~ ((signal_fun s2) t) in
        (f, new_signal);;


(** val signal_neg : signal -> signal, output(t) = -input(t), frequency consistent.*)
let signal_neg s = 
        let new_signal = fun t -> v_neg ((signal_fun s) t) in
        (frequency s, new_signal);;


(** val signal_sub : signal -> signal -> signal, output(t) = input1(t) - input2(t),
    frequency consistent.*)
let signal_sub s1 s2 = signal_add s1 (signal_neg s2);;


(** val signal_mul : signal -> signal -> signal, output(t) = input1(t) * input2(t), 
    frequency consistent.*)
let signal_mul s1 s2 = 
        let f = signal_check_frequency s1 s2 in
        let new_signal = fun t -> ((signal_fun s1) t) *~ ((signal_fun s2) t) in
        (f, new_signal);;


(** val signal_div : signal -> signal -> signal, output(t) = input1(t) / input2(t), 
    frequency consistent.*)
let signal_div s1 s2 =  
        let f = signal_check_frequency s1 s2 in
        let new_signal = fun t -> ((signal_fun s1) t) /~ ((signal_fun s2) t) in
        (f, new_signal);;


(** val signal_delay : signal -> signal -> signal, output(t) = input1(t - input2(t)), 
    Attention: delay dynamic, frequency of output signal equals to that of first input signal.*)
let signal_delay s1 s2 = 
        let s1_mem = factory_add_memory (signal_fun s1) 
            (signal_macro_to_int Delay_Memory_Length_int) in
        let new_signal = fun t -> 
        let delay = (signal_fun s2) t in
                match delay with
                |N i -> if i < 0 then raise (Signal_operation "Delay time < 0.") 
                                else if (t - i) >= 0 then s1_mem (t - i) 
                                else v_zero (s1_mem 0)
                |R f -> let i = int_of_float f in
                                if i < 0 then raise (Signal_operation "Delay time < 0.") 
                                else if (t - i) >= 0 then s1_mem (t - i) 
                                else v_zero (s1_mem 0)
                |Vec (size, vec) -> raise (Signal_operation "Delay time can not be a vector.")
                |Zero -> s1_mem t
                |W -> raise (Signal_operation "Delay time error.")
        in
        (frequency s1, new_signal);;


(** val signal_mem : signal -> signal, equivalent to signal_delay with constant delay 1.*)
let signal_mem s = signal_delay s (1, (fun t -> N 1));;


(** val signal_vectorize : signal -> signal -> signal, output(t)(i) = input1(input2(0) * t + i), 
Attention: vector size n static, frequency of output signal is (1/n * frequency of input1)*)
let signal_vectorize s1 s2 = 
        let size = (signal_fun s2) 0 in
        match size with
        |N size_int ->
                (
                        let new_signal = fun t -> 
                          make_vector size_int (fun i -> (signal_fun s1) (size_int * t + i)) in
                        let new_frequency = (frequency s1) / size_int in
                        (new_frequency, new_signal)
                )
        |_ -> raise (Signal_operation "Vectorize: vector size should be int.");;


(** val signal_serialize : signal -> signal, output(t) = input(floor(t/n))(t%n), 
    with n = size of input(0). 
    Attention: input size unknown in the cas of "rec".*)
let signal_serialize s = 
        let temp0 = (signal_fun s) 0 in
        match temp0 with
        |Vec (size0, vec0) ->
            let new_signal = fun t ->
                (
                        let temp = (signal_fun s) (t/size0) in
                        match temp with
                        |Vec (size, vec) ->
                                if size = size0 then 
                                  vec (t mod size)
                                else 
                                  raise (Signal_operation "Serialize: vector length not consistent.")
                        |_ -> raise (Signal_operation "Serialize: signal type not consistent.")
                )
            in
            let new_frequency = (frequency s) * size0 in
            (new_frequency, new_signal)
        |_ -> raise (Signal_operation "Serialize: input signal should be vector.");;


(** val signal_append : signal -> signal -> signal, symbol "#", 
    appends vectors of the two input signals at each time, frequency consistent.*)
let signal_append s1 s2 = 
        let f = signal_check_frequency s1 s2 in
        let new_signal = fun t -> 
                let temp1 = (signal_fun s1) t in
                let temp2 = (signal_fun s2) t in
                match (temp1, temp2) with
                |(Vec (size1, vec1), Vec (size2, vec2)) ->
                        let new_vec = fun i -> if i < size1 then vec1 i else vec2 (i - size1) in
                        make_vector (size1 + size2) new_vec
                |_ -> raise (Signal_operation "Append: input signals should be vectors.")
        in
        (f, new_signal);;


(** val signal_nth : signal -> signal -> signal, symbol "[]", output(t) = input1(t)(input2(t)), 
    frequency consistent. Attention: selection index dynamic.*)
let signal_nth s1 s2 = 
        let f = signal_check_frequency s1 s2 in
        let new_signal = fun t -> 
                let temp1 = (signal_fun s1) t in
                let temp2 = (signal_fun s2) t in
                match temp1 with
                |Vec (size1, vec1) ->
                (
                        match temp2 with
                        |N i -> vec1 i
                        |R f -> 
                            raise (Signal_operation "Get: second input signal should be int.")
                        |Vec (size2, vec2) -> 
                            raise (Signal_operation "Get: second input signal should be int.")
                        |Zero -> vec1 0
                        |W -> 
                            raise (Signal_operation "Get: second input signal should be int.")
                )
                |_ -> raise (Signal_operation "Get: first input signal should be vector.")
        in
        (f, new_signal);;


(** val signal_floor : signal -> signal, output(t) = v_floor(input(t)), frequency consistent.*)
let signal_floor s = 
        let new_signal = fun t -> v_floor ((signal_fun s) t) in
        (frequency s, new_signal);;


(** val signal_int : signal -> signal, output(t) = v_int(input(t)), frequency consistent.*)
let signal_int s = 
        let new_signal = fun t -> v_int ((signal_fun s) t) in
        (frequency s, new_signal);;


(** val signal_sin : signal -> signal, output(t) = v_sin(input(t)), frequency consistent.*)
let signal_sin s = 
        let new_signal = fun t -> v_sin ((signal_fun s) t) in
        (frequency s, new_signal);;


(** val signal_cos : signal -> signal, output(t) = v_cos(input(t)), frequency consistent.*)
let signal_cos s = 
        let new_signal = fun t -> v_cos ((signal_fun s) t) in
        (frequency s, new_signal);;


(** val signal_atan : signal -> signal, output(t) = v_atan(input(t)), frequency consistent.*)
let signal_atan s = 
        let new_signal = fun t -> v_atan ((signal_fun s) t) in
        (frequency s, new_signal);;


let signal_atantwo s1 s2 = 
        let new_signal = fun t -> v_atantwo ((signal_fun s1) t) ((signal_fun s2) t) in
        (frequency s1, new_signal);;


(** val signal_sqrt : signal -> signal, output(t) = v_sqrt(input(t)), frequency consistent.*)
let signal_sqrt s = 
        let new_signal = fun t -> v_sqrt ((signal_fun s) t) in
        (frequency s, new_signal);;


(** val signal_rdtable : signal -> signal -> signal, 
    output(t) = input1(input2(t)), frequency equals to that of input2. 
    Attention: no memory implemented, very expensive when input1 comes from rec or delays.*)
let signal_rdtable s0 s1 s2 = 
        let memory_length_int = take_off_N ((signal_fun s0) 0) in
        let s1_mem = factory_add_memory (signal_fun s1) memory_length_int in
        let new_signal = fun t ->
                let index = (signal_fun s2) t in
                match index with
                |N i -> s1_mem i
                |R f -> raise (Signal_operation "Rdtable index cannot be float.")
                |Vec (size, vec) -> raise (Signal_operation "Rdtable index cannot be vector.")
                |Zero -> s1_mem 0
                |W -> raise (Signal_operation "Rdtable index cannot be Error.")
        in
        (frequency s2, new_signal);;


(** val signal_mod : signal -> signal -> signal, 
    output(t) = input1(t) % input2(t), frequency consistent.*)
let signal_mod s1 s2 = 
        let f = signal_check_frequency s1 s2 in
        let new_signal = fun t -> v_mod ((signal_fun s1) t) ((signal_fun s2) t) in
        (f, new_signal);;


(** val signal_sup : signal -> signal -> signal, 
    output(t) = input1(t) > input2(t), frequency consistent.*)
let signal_sup s1 s2 = 
        let f = signal_check_frequency s1 s2 in
        let new_signal = fun t -> v_sup ((signal_fun s1) t) ((signal_fun s2) t) in
        (f, new_signal);;


(** val signal_inf : signal -> signal -> signal, 
    output(t) = input1(t) < input2(t), frequency consistent.*)
let signal_inf s1 s2 = 
        let f = signal_check_frequency s1 s2 in
        let new_signal = fun t -> v_inf ((signal_fun s1) t) ((signal_fun s2) t) in
        (f, new_signal);;


(** val signal_select2 : signal -> signal -> signal -> signal,
[signal_select2 si s0 s1] selects s0 or s1 by index si, frequency consistent.*)
let signal_select2 si s0 s1 = 
        let f = signal_check_frequency3 si s0 s1 in
        let new_signal = fun t -> 
                if (signal_fun si) t = N 0 then (signal_fun s0) t
                else if (signal_fun si) t = N 1 then (signal_fun s1) t
                else raise (Signal_operation "select2 index should be 0 or 1.")
        in
        (f, new_signal);;


(** val signal_select3 : signal -> signal -> signal -> signal -> signal,
[signal_select3 si s0 s1 s2] selects s0 or s1 or s2 by index si, frequency consistent.*)
let signal_select3 si s0 s1 s2 = 
        let f = signal_check_frequency4 si s0 s1 s2 in
        let new_signal = fun t -> 
                if (signal_fun si) t = N 0 then (signal_fun s0) t
                else if (signal_fun si) t = N 1 then (signal_fun s1) t
                else if (signal_fun si) t = N 2 then (signal_fun s2) t
                else raise (Signal_operation "select3 index should be 0 or 1 or 2.")
        in
        (f, new_signal);;


(** val signal_prefix : signal -> signal -> signal,
[signal_prefix s0 s1] returns s0(0) if t = 0, s1(t-1) if t > 0, frequency same to s1.*)
let signal_prefix = fun s0 -> fun s1 -> 
        let new_signal = fun t ->
                if t = 0 then (signal_fun s0) 0
                else if t > 0 then (signal_fun s1) t
                else raise (Signal_operation "prefix time cannot be < 0.")
        in
        (frequency s1, new_signal);;