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rx fifo et tx fifo on l'air de fonctionner lors des testbenchs

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Gamenight77
2025-05-06 10:59:08 +02:00
parent 1ca3456ab8
commit 86d4f5ddd2
11 changed files with 799 additions and 306 deletions
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43
Semaine_4/UART_FIFO/IP/verilog/fifo.v Normal file
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module fifo #(
parameter DEPTH = 16,
parameter WIDTH = 8
)(
input wire clk,
input wire wr_en,
input wire[WIDTH-1:0] wr_data,
input wire rd_en,
output wire[WIDTH-1:0] rd_data,
output wire full,
output wire empty
);
reg [WIDTH-1:0] fifo[0:DEPTH-1];
reg [3:0] wr_ptr;
reg [3:0] rd_ptr;
reg [3:0] count;
assign full = (count == DEPTH);
assign empty = (count == 0);
assign rd_data = fifo[rd_ptr];
initial begin
wr_ptr = 0;
rd_ptr = 0;
count = 0;
end
always @(posedge clk) begin
if (wr_en && !full) begin
fifo[wr_ptr] <= wr_data;
wr_ptr <= (wr_ptr + 1) % DEPTH;
count <= count + 1;
end
if (rd_en && !empty) begin
rd_ptr <= (rd_ptr + 1) % DEPTH;
count <= count - 1;
end
end
endmodule

143
Semaine_4/UART_FIFO/IP/verilog/other_rx.v Normal file
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module other_uart_rx
#(
parameter CLK_FRE = 27, //clock frequency(Mhz)
parameter BAUD_RATE = 115200 //serial baud rate
)
(
input clk, //clock input
input rst_n, //asynchronous reset input, low active
output reg[7:0] rx_data, //received serial data
output reg rx_data_valid, //received serial data is valid
input rx_data_ready, //data receiver module ready
input rx_pin //serial data input
);
//calculates the clock cycle for baud rate
localparam CYCLE = CLK_FRE * 1000000 / BAUD_RATE;
//state machine code
localparam S_IDLE = 1;
localparam S_START = 2; //start bit
localparam S_REC_BYTE = 3; //data bits
localparam S_STOP = 4; //stop bit
localparam S_DATA = 5;
reg[2:0] state;
reg[2:0] next_state;
reg rx_d0; //delay 1 clock for rx_pin
reg rx_d1; //delay 1 clock for rx_d0
wire rx_negedge; //negedge of rx_pin
reg[7:0] rx_bits; //temporary storage of received data
reg[15:0] cycle_cnt; //baud counter
reg[2:0] bit_cnt; //bit counter
assign rx_negedge = rx_d1 && ~rx_d0;
always@(posedge clk or negedge rst_n)
begin
if(rst_n == 1'b0)
begin
rx_d0 <= 1'b0;
rx_d1 <= 1'b0;
end
else
begin
rx_d0 <= rx_pin;
rx_d1 <= rx_d0;
end
end
always@(posedge clk or negedge rst_n)
begin
if(rst_n == 1'b0)
state <= S_IDLE;
else
state <= next_state;
end
always@(*)
begin
case(state)
S_IDLE:
if(rx_negedge)
next_state <= S_START;
else
next_state <= S_IDLE;
S_START:
if(cycle_cnt == CYCLE - 1)//one data cycle
next_state <= S_REC_BYTE;
else
next_state <= S_START;
S_REC_BYTE:
if(cycle_cnt == CYCLE - 1 && bit_cnt == 3'd7) //receive 8bit data
next_state <= S_STOP;
else
next_state <= S_REC_BYTE;
S_STOP:
if(cycle_cnt == CYCLE/2 - 1)//half bit cycle,to avoid missing the next byte receiver
next_state <= S_DATA;
else
next_state <= S_STOP;
S_DATA:
if(rx_data_ready) //data receive complete
next_state <= S_IDLE;
else
next_state <= S_DATA;
default:
next_state <= S_IDLE;
endcase
end
always@(posedge clk or negedge rst_n)
begin
if(rst_n == 1'b0)
rx_data_valid <= 1'b0;
else if(state == S_STOP && next_state != state)
rx_data_valid <= 1'b1;
else if(state == S_DATA && rx_data_ready)
rx_data_valid <= 1'b0;
end
always@(posedge clk or negedge rst_n)
begin
if(rst_n == 1'b0)
rx_data <= 8'd0;
else if(state == S_STOP && next_state != state)
rx_data <= rx_bits;//latch received data
end
always@(posedge clk or negedge rst_n)
begin
if(rst_n == 1'b0)
begin
bit_cnt <= 3'd0;
end
else if(state == S_REC_BYTE)
if(cycle_cnt == CYCLE - 1)
bit_cnt <= bit_cnt + 3'd1;
else
bit_cnt <= bit_cnt;
else
bit_cnt <= 3'd0;
end
always@(posedge clk or negedge rst_n)
begin
if(rst_n == 1'b0)
cycle_cnt <= 16'd0;
else if((state == S_REC_BYTE && cycle_cnt == CYCLE - 1) || next_state != state)
cycle_cnt <= 16'd0;
else
cycle_cnt <= cycle_cnt + 16'd1;
end
//receive serial data bit data
always@(posedge clk or negedge rst_n)
begin
if(rst_n == 1'b0)
rx_bits <= 8'd0;
else if(state == S_REC_BYTE && cycle_cnt == CYCLE/2 - 1)
rx_bits[bit_cnt] <= rx_pin;
else
rx_bits <= rx_bits;
end
endmodule

133
Semaine_4/UART_FIFO/IP/verilog/other_tx.v Normal file
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module other_uart_tx
#(
parameter CLK_FRE = 27, //clock frequency(Mhz)
parameter BAUD_RATE = 115200 //serial baud rate
)
(
input clk, //clock input
input rst_n, //asynchronous reset input, low active
input[7:0] tx_data, //data to send
input tx_data_valid, //data to be sent is valid
output reg tx_data_ready, //send ready
output tx_pin //serial data output
);
//calculates the clock cycle for baud rate
localparam CYCLE = CLK_FRE * 1000000 / BAUD_RATE;
//state machine code
localparam S_IDLE = 1;
localparam S_START = 2;//start bit
localparam S_SEND_BYTE = 3;//data bits
localparam S_STOP = 4;//stop bit
reg[2:0] state;
reg[2:0] next_state;
reg[15:0] cycle_cnt; //baud counter
reg[2:0] bit_cnt;//bit counter
reg[7:0] tx_data_latch; //latch data to send
reg tx_reg; //serial data output
assign tx_pin = tx_reg;
always@(posedge clk or negedge rst_n)
begin
if(rst_n == 1'b0)
state <= S_IDLE;
else
state <= next_state;
end
always@(*)
begin
case(state)
S_IDLE:
if(tx_data_valid == 1'b1)
next_state <= S_START;
else
next_state <= S_IDLE;
S_START:
if(cycle_cnt == CYCLE - 1)
next_state <= S_SEND_BYTE;
else
next_state <= S_START;
S_SEND_BYTE:
if(cycle_cnt == CYCLE - 1 && bit_cnt == 3'd7)
next_state <= S_STOP;
else
next_state <= S_SEND_BYTE;
S_STOP:
if(cycle_cnt == CYCLE - 1)
next_state <= S_IDLE;
else
next_state <= S_STOP;
default:
next_state <= S_IDLE;
endcase
end
always@(posedge clk or negedge rst_n)
begin
if(rst_n == 1'b0)
begin
tx_data_ready <= 1'b0;
end
else if(state == S_IDLE)
if(tx_data_valid == 1'b1)
tx_data_ready <= 1'b0;
else
tx_data_ready <= 1'b1;
else if(state == S_STOP && cycle_cnt == CYCLE - 1)
tx_data_ready <= 1'b1;
end
always@(posedge clk or negedge rst_n)
begin
if(rst_n == 1'b0)
begin
tx_data_latch <= 8'd0;
end
else if(state == S_IDLE && tx_data_valid == 1'b1)
tx_data_latch <= tx_data;
end
always@(posedge clk or negedge rst_n)
begin
if(rst_n == 1'b0)
begin
bit_cnt <= 3'd0;
end
else if(state == S_SEND_BYTE)
if(cycle_cnt == CYCLE - 1)
bit_cnt <= bit_cnt + 3'd1;
else
bit_cnt <= bit_cnt;
else
bit_cnt <= 3'd0;
end
always@(posedge clk or negedge rst_n)
begin
if(rst_n == 1'b0)
cycle_cnt <= 16'd0;
else if((state == S_SEND_BYTE && cycle_cnt == CYCLE - 1) || next_state != state)
cycle_cnt <= 16'd0;
else
cycle_cnt <= cycle_cnt + 16'd1;
end
always@(posedge clk or negedge rst_n)
begin
if(rst_n == 1'b0)
tx_reg <= 1'b1;
else
case(state)
S_IDLE,S_STOP:
tx_reg <= 1'b1;
S_START:
tx_reg <= 1'b0;
S_SEND_BYTE:
tx_reg <= tx_data_latch[bit_cnt];
default:
tx_reg <= 1'b1;
endcase
end
endmodule

145
Semaine_4/UART_FIFO/IP/verilog/uart_rx.v Normal file
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module uart_rx #(
parameter CLK_FREQ = 27_000_000,
parameter BAUD_RATE = 115200
)(
input clk, //clock input
input rst_p, //asynchronous reset input, high active
input rx_enable, //data receiver module ready
input rx_pin, //serial data input
output reg[7:0] rx_data, //received serial data
output reg rx_received //received serial data is valid
);
localparam CYCLE = CLK_FREQ / BAUD_RATE;
//state machine code
localparam S_IDLE = 1;
localparam S_START = 2; //start bit
localparam S_REC_BYTE = 3; //data bits
localparam S_STOP = 4; //stop bit
localparam S_DATA = 5;
reg[2:0] state;
reg[2:0] next_state;
reg rx_d0; //delay 1 clock for rx_pin
reg rx_d1; //delay 1 clock for rx_d0
wire rx_negedge; //negedge of rx_pin
reg[7:0] rx_bits; //temporary storage of received data
reg[15:0] cycle_cnt; //baud counter
reg[2:0] bit_cnt; //bit counter
assign rx_negedge = rx_d1 && ~rx_d0; // Front déscendant
always@(posedge clk or posedge rst_p) // Filtrage du signial
begin
if(rst_p == 1'b1)begin
rx_d0 <= 1'b0;
rx_d1 <= 1'b0;
end else begin
rx_d0 <= rx_pin;
rx_d1 <= rx_d0;
end
end
always@(posedge clk or posedge rst_p)begin // Compteur d'etat
if(rst_p == 1'b1)
state <= S_IDLE;
else
state <= next_state;
end
always@(*)begin
case(state)
S_IDLE:
if(rx_negedge) // Detection du start bit
next_state = S_START;
else
next_state = S_IDLE;
S_START:
if(cycle_cnt == CYCLE - 1) //one data cycle
next_state = S_REC_BYTE;
else
next_state = S_START;
S_REC_BYTE:
if(cycle_cnt == CYCLE - 1 && bit_cnt == 3'd7) //receive 8bit data
next_state = S_STOP;
else
next_state = S_REC_BYTE;
S_STOP:
if(cycle_cnt == CYCLE/2 - 1) //half bit cycle,to avoid missing the next byte receiver
next_state = S_DATA;
else
next_state = S_STOP;
S_DATA:
if(rx_enable) //data receive complete
next_state = S_IDLE;
else
next_state = S_DATA;
default:
next_state = S_IDLE;
endcase
end
always@(posedge clk or posedge rst_p)
begin
if(rst_p == 1'b1)
rx_received <= 1'b0;
else if(state == S_STOP && next_state != state)
rx_received <= 1'b1;
else if(state == S_DATA && rx_enable)
rx_received <= 1'b0;
end
always@(posedge clk or posedge rst_p)
begin
if(rst_p == 1'b1)
rx_data <= 8'd0;
else if(state == S_STOP && next_state != state)
rx_data <= rx_bits;//latch received data
end
always@(posedge clk or posedge rst_p)
begin
if(rst_p == 1'b1)
begin
bit_cnt <= 3'd0;
end
else if(state == S_REC_BYTE)
if(cycle_cnt == CYCLE - 1)
bit_cnt <= bit_cnt + 3'd1;
else
bit_cnt <= bit_cnt;
else
bit_cnt <= 3'd0;
end
always@(posedge clk or posedge rst_p)
begin
if(rst_p == 1'b1)
cycle_cnt <= 16'd0;
else if((state == S_REC_BYTE && cycle_cnt == CYCLE - 1) || next_state != state)
cycle_cnt <= 16'd0;
else
cycle_cnt <= cycle_cnt + 16'd1;
end
//receive serial data bit data
always@(posedge clk or posedge rst_p)
begin
if(rst_p == 1'b1)
rx_bits <= 8'd0;
else if(state == S_REC_BYTE && cycle_cnt == CYCLE/2 - 1)
rx_bits[bit_cnt] <= rx_pin;
else
rx_bits <= rx_bits;
end
endmodule

131
Semaine_4/UART_FIFO/IP/verilog/uart_tx.v Normal file
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module uart_tx #(
parameter CLK_FREQ = 27_000_000,
parameter BAUD_RATE = 115200
)(
input wire clk,
input wire rst_p,
input wire[7:0] data,
input wire tx_enable,
output reg tx_ready,
output wire tx
);
localparam CYCLE = CLK_FREQ / BAUD_RATE;
localparam IDLE = 2'd0;
localparam START = 2'd1;
localparam DATA = 2'd2;
localparam STOP = 2'd3;
reg [1:0] state = IDLE;
reg [1:0] next_state;
reg [15:0] cycle_cnt; //baud counter
reg tx_reg;
reg [2:0] bit_cnt;
reg [7:0] tx_data_latch = 0;
assign tx = tx_reg;
always@(posedge clk or posedge rst_p)begin // Avance d'etat
if(rst_p == 1'b1)
state <= IDLE;
else
state <= next_state;
end
always@(*) begin
case(state)
IDLE:
if(tx_enable == 1'b1)
next_state = START;
else
next_state = IDLE;
START:
if(cycle_cnt == CYCLE - 1)
next_state = DATA;
else
next_state = START;
DATA:
if(cycle_cnt == CYCLE - 1 && bit_cnt == 3'd7)
next_state = STOP;
else
next_state = DATA;
STOP:
if(cycle_cnt == CYCLE - 1)
next_state = IDLE;
else
next_state = STOP;
default:
next_state = IDLE;
endcase
end
always@(posedge clk or posedge rst_p)begin // tx_ready block
if(rst_p == 1'b1)
tx_ready <= 1'b0; // Reset
else if(state == IDLE && tx_enable == 1'b1)
tx_ready <= 1'b0; // Pas prêt tant que les données sont valides
else if(state == IDLE)
tx_ready <= 1'b1;
else if(state == STOP && cycle_cnt == CYCLE - 1)
tx_ready <= 1'b1; // Prêt une fois le bit STOP envoyé
else
tx_ready <= tx_ready; // Reste inchangé dans d'autres cas
end
always@(posedge clk or posedge rst_p) begin // tx_data_latch block
if(rst_p == 1'b1) begin
tx_data_latch <= 8'd0;
end else if(state == IDLE && tx_enable == 1'b1) begin
tx_data_latch <= data; // Charger les données de data dans tx_data_latch
end
end
always@(posedge clk or posedge rst_p)begin // DATA bit_cnt block
if(rst_p == 1'b1)begin
bit_cnt <= 3'd0;
end else if(state == DATA)
if(cycle_cnt == CYCLE - 1)
bit_cnt <= bit_cnt + 3'd1;
else
bit_cnt <= bit_cnt;
else
bit_cnt <= 3'd0;
end
always@(posedge clk or posedge rst_p)begin // Cycle counter
if(rst_p == 1'b1)
cycle_cnt <= 16'd0;
else if((state == DATA && cycle_cnt == CYCLE - 1) || next_state != state)
cycle_cnt <= 16'd0;
else
cycle_cnt <= cycle_cnt + 16'd1;
end
always@(posedge clk or posedge rst_p)begin // tx state managment
if(rst_p == 1'b1)
tx_reg <= 1'b1;
else
case(state)
IDLE,STOP:
tx_reg <= 1'b1;
START:
tx_reg <= 1'b0;
DATA:
tx_reg <= tx_data_latch[bit_cnt]; // SENDING BYTE HERE
default:
tx_reg <= 1'b1;
endcase
end
endmodule