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(*
 * CBG SQUANDERER EVENT DRIVEN SIMULATOR cbgeds.sml
 *
 * A basic EDA event driven simulator written in sml  mosml.
 * (C) 1999 DJ Greaves.
 * 
 *)


(*--------------------------------------------------------*)
(*
 *  Datastructure for the model and netlist.
 * 
 *
 *  A net has a string name and a width.
 *  A net may be high z, dont know or contain an integer from 0 up to 2**width - 1.
 *  A net has a list of driving and reading models.
 *  A model has a unique instance name, a delay, a form and a list of nets it has contact with.
 *  It also may have some internal state, held in the last field.
 *)

datatype value_t = V_n of int | V_z | V_x;

datatype m_t = M_AND | M_OR | M_INV | M_XOR | M_DFF | M_BUFIF | M_TLATCH | M_CLOCK;

datatype internal_state_t =
  IS_NONE
| IS_DFF of value_t ref
| IS_CLOCK of int ref
;

datatype 
   net_t = NET of value_t ref * string * int * model_t list ref * model_t list ref 

and 
  model_t = MODEL of string * int * m_t * net_t list * internal_state_t
;

(* Constructor for a new net *)
fun net(s, w) = NET(ref V_x, s, w, ref nil, ref nil);

(* Function to set the new value of a net and return a list of
 * any models that must be executed because they are sensitive to
 * changes in this net.
 *)
fun net_setvalue(NET(value, s, w, drivers, sensitives), new_value) =
	if (!value = new_value) then nil
	else 
	(
	value := new_value;
	!sensitives
	)
;

(* Function to read current value of a net *)
fun netvalue(NET(value, s, w, drivers, sensitives)) = !value
;

(* Constructor for a new model.  Connects itself to each net in use. *)
fun model(s, d, form, output_nets, input_nets) =
    let val internal_state =
                 if (form = M_DFF) then IS_DFF(ref V_x) else
                 if (form = M_CLOCK) then IS_CLOCK(ref 0) else
                        IS_NONE
        val nets = output_nets @ input_nets
        val m = MODEL(s, d, form, nets, internal_state)
        fun connect_output(NET(v, s, w, drivers, sensitives)) = drivers := m :: (!drivers)
        fun connect_input(NET(v, s, w, drivers, sensitives)) = sensitives := m :: (!sensitives)
        val _ = app connect_output output_nets
        val _ = app connect_input input_nets
        in m
        end
;

(*--------------------------------------------------------*)
(*
 *  Datastructure for an event list and also the current global time, tnow.
 *
 *  The fields of an event are the time that it occurs, the net it changes and 
 *  the new value on that net. It also has a pointer to the next event in time
 *  order.
 *)
type time_t = int;
val tnow = ref 0;

datatype event_t =
   EVENT of time_t * net_t * value_t * event_t ref
|  EMPTY
;

val eventlist = ref EMPTY;

(* Constructor for a new event that also inserts it at the correct point in the sorted event list. *)
fun event(time, net, value) = 
    let fun a e = case !e of
		(A as EMPTY) => e := EVENT(time, net, value, ref A)
	      |	(A as EVENT(t, n, v, e')) => if (t > time) then e := EVENT(time, net, value, ref A) else a e' 
	in a eventlist
	end
;

(*--------------------------------------------------------*)
(*
 *  Some code for example models is provided here. These models
 *  are just the standard logic gates found in most digital
 *  electronic systems.
 *)
fun 
   example_models(MODEL(iname, delay, M_INV, nets, _)) =
    let val input = hd(tl nets)
	val output = hd nets
	fun invert (V_n 0) = V_n 1
	|   invert (V_n 1) = V_n 0
	|   invert (other) = V_x
	in event(!tnow+delay, output, invert (netvalue input))
	end

|  example_models(MODEL(iname, delay, M_AND, nets, _)) =
    let val i1 = hd(tl(tl nets))
        val i2 = hd(tl nets)
	val output = hd nets
	fun AND (V_n 0, _) = V_n 0
	|   AND (_, V_n 0) = V_n 0
	|   AND (V_n 1, Vn_1) = V_n 1
	|   AND (other) = V_x
	in event(!tnow+delay, output, AND (netvalue i1, netvalue i2))
	end

|  example_models(MODEL(iname, delay, M_OR, nets, _)) =
    let val i1 = hd(tl(tl nets))
        val i2 = hd(tl nets)
	val output = hd nets
	fun OR (V_n 1, _) = V_n 1
	|   OR (_, V_n 1) = V_n 1
	|   OR (V_n 0, Vn_0) = V_n 0
	|   OR (other) = V_x
	in event(!tnow+delay, output, OR (netvalue i1, netvalue i2))
	end

|  example_models(MODEL(iname, delay, M_DFF, nets, IS_DFF(old_clk))) =
    let val d = netvalue(hd(tl(tl nets)))
        val clk = netvalue(hd(tl nets))
	val output = hd nets
	(* Positive edge detector here *)
	fun posedge (V_n 1, V_n 0) = true
	|   posedge (_, _) = false
	val active_edge = posedge(clk, !old_clk)
	val _ = old_clk := clk
	in if (active_edge) then event(!tnow+delay, output, d) else ()
	end

|  example_models(MODEL(iname, delay, M_CLOCK, nets, IS_CLOCK(state))) =
    let val output = hd nets
        val nv = 1 - (!state)
        val _ = state := nv
        in event(!tnow+delay, output, V_n nv)
        end

|  example_models(MODEL(iname, delay, other, nets, _)) =
	print ("No model provided for instance " ^ iname ^ "\n")
;

(*--------------------------------------------------------*)
(*
 * Dispatcher for a single event. Takes the event from the head of the
 * event queue, updates the net and the current time and activates
 * all of the models that are sensitive to that net.
 *)


fun dispatch_one_event() =
	if (!eventlist = EMPTY) then print("simulation finished - no more events\n")
	else 	
	let val EVENT(time, net, value, e') = !eventlist
	in
	(
	eventlist := !e';
	tnow := time;
	app example_models (net_setvalue(net, value))
	) end
;


(*--------------------------------------------------------*)
(*
 * Top-level simulation
 * 
 *)

fun main() =
   (

   (*   ... put the code to create your circuit here ... *)

   while (!eventlist <> EMPTY)  do dispatch_one_event()
   )
;


val _ = quit();

(* eof cbg *)