finite state machine verilog

I was wondering if someone could shed some light on how to go about coding a pattern fsm in Verilog that produces the 4 different patterns on 8 LEDs and the LEDs change every tick pulse. I know that I should be using state register and combinational next state logic, but I'm not sure how to go about writing it.

I hope someone could provide an example.

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What 4 patterns, and how do the LEDs change? Are you saying there are 4 static patterns and you just display them sequentially with each clock pulse, or is it 4 dynamic moving patterns where the FSM change is triggered by a button or something? –  Dax Fohl Sep 12 '12 at 16:17
yes, there are 4 buttons to trigger 4 different modes, each mode will trigger 8 LEDs to move in a pattern, i.e. left to right, right to left. –  intensified Sep 13 '12 at 2:36

It is hard to provide an example without knowing every detail... But the simplest case can look something like a state machine with four states and asynchronous reset. States change on every raising edge of the clock. For every state, 7-bit of data is "driven" to the led (you can extend it to 8 LEDs no problem, just more typing):

``````module fsm_example(clk, reset_n, data);

input wire clk;     // Clock input
input wire reset_n; // Asynchronous reset (active low)
output reg [6:0] data; // Data driven to seven-segment display...

// Constant state enumeration
localparam STATE_0 = 2'd0;
localparam STATE_1 = 2'd1;
localparam STATE_2 = 2'd2;
localparam STATE_3 = 2'd3;

// Current FSM state (up to 2 bits, enough to hold values from 0 to 3)
reg [1:0] state;

// Clock-driven state machine. Changes state on every
// raising edge of the clock.
always @ (posedge clk or negedge reset_n) begin
if (!reset_n) begin
state <= STATE_0;
end else begin
case (state)
STATE_0: state <= STATE_1;
STATE_1: state <= STATE_2;
STATE_2: state <= STATE_3;
STATE_3: state <= STATE_0;
endcase
end
end

// State to output data mapping.
always @ (state) begin
case (state)
STATE_0: data = 7'b0111111; // 0x0
STATE_1: data = 7'b0000110; // 0x1
STATE_2: data = 7'b1011011; // 0x2
STATE_3: data = 7'b1001111; // 0x3
endcase
end

endmodule
``````

The code is pretty straight forward if you know a bit of Verilog. Hope it helps.

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