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[Faustine.git] / interpreter / signal.ml

(**
        Module: Signal  
        Description: signal definition and operations.
        @author WANG Haisheng   
        Created: 03/06/2013     Modified: 03/06/2013
*)

open Types;;
open Basic;;
open Value;;

exception Signal_operation of string;;

let delay_memory_length = 10000;;

class rate : int -> int -> rate_type = 
  fun (num_init : int) ->
    fun (denom_init : int) ->
      let rec pgcd : int -> int -> int = 
        fun i1 -> fun i2 ->
          let r = i1 mod i2 in 
          if r = 0 then i2 else pgcd i2 r in
      let factor = 
        if denom_init = 0 then 
          raise (Signal_operation "sample rate denominater = 0.")
        else 
          pgcd (abs num_init) (abs denom_init) in
      object (self)
        val _num = num_init / factor
        val _denom = denom_init / factor
        method num = _num
        method denom = _denom
        method to_int = 
          self#num / self#denom
        method to_float = 
          (float_of_int self#num) /. (float_of_int self#denom)
        method to_string = 
          (string_of_int self#num) ^ "/" ^ (string_of_int self#denom)
        method equal : rate_type -> bool = 
          fun (r : rate_type) -> (self#num = r#num) && (self#denom = r#denom)
        method mul : int -> rate_type = 
          fun (i : int) -> new rate (self#num * i) self#denom
        method div : int -> rate_type = 
          fun (i : int) -> new rate self#num (self#denom * i)
      end
          

class signal : rate_type -> (time -> value_type) -> signal_type = 
  fun (freq_init : rate_type) ->
    fun (func_init : time -> value_type) ->
      object (self)
        val mutable signal_func = func_init
        val mutable memory_length = 0
        method frequency = freq_init
        method at = signal_func

        method private check_freq : signal_type list -> rate_type = 
          fun (sl : signal_type list) ->
            let check : rate_type -> signal_type -> rate_type = 
              fun (f : rate_type) ->
                fun (s : signal_type) ->
                  if f#equal s#frequency || s#frequency#num = 0 then f
                  else if f#num = 0 then s#frequency
                  else raise (Signal_operation "frequency not matched.") in
            List.fold_left check self#frequency sl

        method add_memory : int -> unit = 
          fun (length : int) ->
            assert (length >= 0);
            if memory_length >= length then ()
            else
              let memory = Hashtbl.create length in
              let func : time -> value = 
                fun (t : time) ->
                  try Hashtbl.find memory t
                  with Not_found ->
                    let result = func_init t in
                    let () = Hashtbl.replace memory t result in
                    let () = 
                      if (t - length) >= 0 then
                        Hashtbl.remove memory (t - length)
                      else () in
                    result in
              memory_length <- length;
              signal_func <- func

        method private delay_by : int -> time -> value = 
          fun i -> fun t ->
            if (t - i) >= 0 then
              self#at (t - i)
            else if t >= 0 && (t - i) < 0 then
              (self#at 0)#zero
            else raise (Signal_operation "Delay time < 0.")

        method private prim1 : 
            (time -> value_type) -> signal_type = 
              fun (func : time -> value_type) ->
                let freq = self#frequency in
                new signal freq func 

        method private prim2 : 
            (time -> value_type -> value_type) -> signal_type -> signal_type = 
          fun (func_binary : time -> value_type -> value_type) ->
            fun (s : signal_type) ->
              let freq = self#check_freq [s] in
              let func = fun t -> (func_binary t) (s#at t) in
              new signal freq func

        method neg = self#prim1 (fun t -> (self#at t)#neg)
        method floor = self#prim1 (fun t -> (self#at t)#floor)
        method ceil = self#prim1 (fun t -> (self#at t)#ceil)
        method rint = self#prim1 (fun t -> (self#at t)#rint)
        method sin = self#prim1 (fun t -> (self#at t)#sin)
        method asin = self#prim1 (fun t -> (self#at t)#asin)
        method cos = self#prim1 (fun t -> (self#at t)#cos)
        method acos = self#prim1 (fun t -> (self#at t)#acos)
        method tan = self#prim1 (fun t -> (self#at t)#tan)
        method atan = self#prim1 (fun t -> (self#at t)#atan)
        method exp = self#prim1 (fun t -> (self#at t)#exp)
        method sqrt = self#prim1 (fun t -> (self#at t)#sqrt)
        method ln = self#prim1 (fun t -> (self#at t)#ln)
        method lg = self#prim1 (fun t -> (self#at t)#lg)
        method int = self#prim1 (fun t -> (self#at t)#int)
        method float = self#prim1 (fun t -> (self#at t)#float)
        method abs = self#prim1 (fun t -> (self#at t)#abs)

        method add = self#prim2 (fun t -> (self#at t)#add)
        method sub = self#prim2 (fun t -> (self#at t)#sub)
        method mul = self#prim2 (fun t -> (self#at t)#mul)
        method div = self#prim2 (fun t -> (self#at t)#div)
        method power = self#prim2 (fun t -> (self#at t)#power)
        method _and = self#prim2 (fun t -> (self#at t)#_and)
        method _or = self#prim2 (fun t -> (self#at t)#_or)
        method _xor = self#prim2 (fun t -> (self#at t)#_xor)
        method atan2 = self#prim2 (fun t -> (self#at t)#atan2)
        method _mod = self#prim2 (fun t -> (self#at t)#_mod)
        method fmod = self#prim2 (fun t -> (self#at t)#fmod)
        method remainder = self#prim2 (fun t -> (self#at t)#remainder)
        method gt = self#prim2 (fun t -> (self#at t)#gt)
        method lt = self#prim2 (fun t -> (self#at t)#lt)
        method geq = self#prim2 (fun t -> (self#at t)#geq)
        method leq = self#prim2 (fun t -> (self#at t)#leq)
        method eq = self#prim2 (fun t -> (self#at t)#eq)
        method neq = self#prim2 (fun t -> (self#at t)#neq)
        method max = self#prim2 (fun t -> (self#at t)#max)
        method min = self#prim2 (fun t -> (self#at t)#min)
        method shl = self#prim2 (fun t -> (self#at t)#shl)
        method shr = self#prim2 (fun t -> (self#at t)#shr)

        method delay : signal_type -> signal_type =
          fun (s : signal_type) ->
            let freq = self#check_freq [s] in
            let () = self#add_memory delay_memory_length in
            let func : time -> value_type = 
              fun (t : time) ->
                let i = (s#at t)#to_int in
                self#delay_by i t  in
            new signal freq func

        method mem : signal_type = 
          let freq = self#frequency in
          let () = self#add_memory 1 in
          let func = fun (t : time) -> self#delay_by 1 t in
          new signal freq func

        method rdtable : signal_type -> signal_type -> signal_type = 
          fun (s_size : signal_type) ->
            fun (s_index : signal_type) ->
              let freq = self#check_freq [s_index] in
              let () = self#add_memory ((s_size#at 0)#to_int) in
              let func : time -> value_type = fun t -> 
                self#at ((s_index#at t)#to_int) in
              new signal freq func

        method rwtable : signal_type -> signal_type -> 
          signal_type -> signal_type -> signal_type = 
            fun init -> fun wstream -> fun windex -> fun rindex ->
              let freq = self#check_freq [init; wstream; windex; rindex] in
              let () = init#add_memory ((self#at 0)#to_int) in
              let () = wstream#add_memory ((self#at 0)#to_int) in
              let func : time -> value_type = fun (ti : time) -> 
                let rec table : time -> index -> value_type = 
                  fun t -> fun i -> 
                    if t > 0 then
                      (if i = (windex#at t)#to_int then (wstream#at t)
                      else table (t - 1) i)
                    else if t = 0 then
                      (if i = (windex#at 0)#to_int then (wstream#at 0)
                      else init#at i)
                    else raise (Signal_operation "signal time should be > 0") in
                table ti ((rindex#at ti)#to_int) in
              new signal freq func

        method select2 : signal_type -> signal_type -> signal_type =
          fun s_first -> 
            fun s_second ->
              let freq = self#check_freq [s_first; s_second] in
              let func : time -> value_type = 
                fun t -> let i = (self#at t)#to_int in
                if i = 0 then s_first#at t
                else if i = 1 then s_second#at t
                else raise (Signal_operation "select2 index 0|1.") in
              new signal freq func

        method select3 : 
            signal_type -> signal_type -> signal_type -> signal_type =
              fun s_first -> fun s_second -> fun s_third ->
                let freq = self#check_freq [s_first; s_second; s_third] in
                let func : time -> value_type = 
                  fun t -> let i = (self#at t)#to_int in
                  if i = 0 then s_first#at t
                  else if i = 1 then s_second#at t
                  else if i = 2 then s_third#at t
                  else raise (Signal_operation "select2 index 0|1.") in
                new signal freq func    
                    
        method prefix : signal_type -> signal_type =
            fun (s_init : signal_type) ->
              let () = self#add_memory 1 in
              let func : time -> value_type = 
                fun t ->
                  if t = 0 then s_init#at 0
                  else if t > 0 then self#at (t - 1) 
                  else raise (Signal_operation "prefix time < 0.") in
              new signal self#frequency func


        method vectorize : signal_type -> signal_type =
          fun s_size ->
            let size = (s_size#at 0)#to_int in
            if size <= 0 then      
              raise (Signal_operation "Vectorize: size <= 0.")
            else 
              let freq = self#frequency#div size in
              let func : time -> value_type = 
                fun t ->
                  let vec = fun i -> (self#at (size * t + i))#get in
                  new value (Vec (new vector size vec)) in
              new signal freq func

        method serialize : signal_type = 
          let size = 
            match (self#at 0)#get with
            | Vec vec -> vec#size
            | _ -> raise (Signal_operation "Serialize: scalar input.") in
          let freq = self#frequency#mul size in
          let func : time -> value_type = 
            fun t -> 
              match (self#at (t/size))#get with
              | Vec vec -> new value (vec#nth (t mod size))
              | _ -> raise (Signal_operation 
                              "Serialize: signal type not consistent.") in
          new signal freq func

        method vconcat : signal_type -> signal_type = 
          fun s ->
            let freq = self#check_freq [s] in
            let func : time -> value_type = 
              fun t ->
                match ((self#at t)#get, (s#at t)#get) with
                | (Vec vec1, Vec vec2) ->
                    let size1 = vec1#size in
                    let size2 = vec2#size in
                    let size = size1 + size2 in
                    let vec = fun i -> 
                      if i < size1 then vec1#nth i
                      else vec2#nth (i - size1) in
                    new value (Vec (new vector size vec))
                | _ -> raise (Signal_operation "Vconcat: scalar.") in
            new signal freq func

        method vpick : signal_type -> signal_type = 
          fun s_index ->
            let freq = self#check_freq [s_index] in
            let func : time -> value_type = 
              fun t -> 
                let i = (s_index#at t)#to_int in
                match (self#at t)#get with
                | Vec vec -> new value (vec#nth i)
                | _ -> raise (Signal_operation "Vpick: scalar.") in
            new signal freq func

      end;;