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|
// moore_recursive_template.v
module moore_recursive_template
#( parameter
param1 : <value>,
param2 : <value>
)
(
input wire clk, reset,
input wire [<size>] input1, input2, ...,
output reg [<size>] output1, output2, new_output1, new_output2
);
localparam [<size_state>] // for 4 states : size_state = 1:0
s0 = 0,
s1 = 1,
s2 = 2,
... ;
reg[<size_state>] state_reg, state_next;
// timer
localparam T1 = <value>;
localparam T2 = <value>;
localparam T3 = <value>;
...
reg [<size>] t; //<size> should be able to store max(T1, T2, T3)
// recursive : feedback register
reg [<size>] r1_reg, r1_next;
reg [<size>] r2_reg, r2_next, ;
...
// state register : state_reg
// This always-block contains sequential part & all the D-FF are
// included in this always-block. Hence, only 'clk' and 'reset' are
// required for this always-block.
always(posedge clk, posedge reset)
begin
if (reset) begin
state_reg <= s1;
end
else begin
state_reg <= state_next;
end
end
// timer (optional)
always @(posedge clk, posedge reset) begin
if (reset) begin
t <= 0;
end
else begin
if state_reg != state_next then // state is changing
t <= 0;
else
t <= t + 1;
end
end
// feedback registers: to feedback the outputs
always @(posedge clk, posedge reset)
begin
if (reset) begin
r1_reg <= <initial_value>;
r2_reg <= <initial_value>;
...
end
else begin
r1_reg <= r1_next;
r2_reg <= r2_next;
...
end
end
// next state logic : state_next
// This is combinational of the sequential design,
// which contains the logic for next-state
// include all signals and input in sensitive-list except state_next
always @(input1, input2, state_reg) begin
state_next = state_reg; // default state_next
r1_next = r1_reg; // default next-states
r2_next = r2_reg;
...
case (state_reg)
s0 : begin
if <condition> & r1_reg == <value> & t >= T1-1 begin // if (input1 = '01') then
state_next = s1;
r1_next = <value>;
r2_next = <value>;
...
end
elsif <condition> & r2_reg == <value> & t >= T2-1 begin // add all the required conditions
state_next = <value>;
r1_next = <value>;
...
end
else begin // remain in current state
state_next = s0;
r2_next = <value>;
...
end
end
s1 : begin
...
end case;
end process;
// next state logic and outputs
// This is combinational of the sequential design,
// which contains the logic for next-state and outputs
// include all signals and input in sensitive-list except state_next
always @(input1, input2, ..., state_reg) begin
state_next = state_reg; // default state_next
// default outputs
output1 = <value>;
output2 = <value>;
...
// default next-states
r1_next = r1_reg;
r2_next = r2_reg;
...
case (state_reg)
s0 : begin
output1 = <value>;
output2 = <value>;
if (<condition> & r1_reg = <value> & t >= T1-1) begin // if (input1 = 2'b01) then
...
r1_next = <value>;
r2_next = <value>;
...
state_next = s1;
end
else if (<condition> & r2_reg = <value> & t >= T2-1) begin // add all the required coditions
r1_next = <value>;
...
state_next = ...;
end
else begin // remain in current state
r2_next = <value>;
...
state_next = s0;
end
end
s1 : begin
output1 = <value>;
output2 = <value>;
if (<condition> & r1_reg = <value> & t >= T3-1) begin // if (input1 = 2'b01) then
...
r1_next = <value>;
r2_next = <value>;
...
state_next = s1;
end
else if (<condition> & r2_reg = <value> & t >= T1-1) begin // add all the required coditions
r1_next = <value>;
...
state_next = ...;
end
else begin // remain in current state
r2_next = <value>;
...
state_next = s1;
end
end
endcase
end
// optional D-FF to remove glitches
always @(posedge clk, posedge reset)
begin
if (reset) begin
new_output1 <= ... ;
new_output2 <= ... ;
end
else begin
new_output1 <= output1;
new_output2 <= output2;
end
end
endmodule
|