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NOC

master
Naga Sitaram M 1 年之前
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b05a208091
共有 6 個檔案被更改,包括 740 行新增0 行删除
  1. +143
    -0
      RISC_V/NOC/router_fifo.v
  2. +142
    -0
      RISC_V/NOC/router_fsm.v
  3. +119
    -0
      RISC_V/NOC/router_reg.v
  4. +177
    -0
      RISC_V/NOC/router_sync.v
  5. +36
    -0
      RISC_V/NOC/router_top.v
  6. +123
    -0
      RISC_V/NOC/router_top_tb.v

+ 143
- 0
RISC_V/NOC/router_fifo.v 查看文件

@@ -0,0 +1,143 @@
module router_fifo(data_out,full,empty,clock,resetn,soft_reset,data_in,write_enb,read_enb,lfd_state);
parameter DATA_WIDTH = 9,
DATA_DEPTH=16,
DATA_ADDR=4;
input clock,resetn,write_enb,read_enb,soft_reset,lfd_state;
input [7:0]data_in;
output reg [7:0]data_out;
output full,empty;
reg temp;
integer i;
reg [3:0]rd_pntr,wr_pntr;
//counters the no.of write and read signals
reg [4:0]f_e_count;
// counters the no.of payloads and parity
reg [5:0]counter;
reg [8:0] mem [0:15];
assign full = (f_e_count==5'b10000);
assign empty = (f_e_count ==5'b00000);
always @(posedge clock ) begin
if (!resetn) begin
temp<=1'b0;
end
else if (soft_reset) begin
temp<=1'b0;
end
else
temp<=lfd_state;
end
//write pointer and read pointer logic
always @(posedge clock)
begin
if(!resetn)
wr_pntr<=4'b0000;
else if (soft_reset)
wr_pntr<=4'b0000;
else if (write_enb==1 && full == 0)
wr_pntr<=wr_pntr+1'b1;
else
wr_pntr<=wr_pntr;
end
always @(posedge clock)
begin
if(!resetn)
rd_pntr<=4'b0000;
else if (soft_reset)
rd_pntr<=4'b0000;
else if (read_enb==1 && empty == 0)
rd_pntr<=rd_pntr+1'b1;
else
rd_pntr<=rd_pntr;
end
// write operation
always @(posedge clock ) begin
if (!resetn) begin
for (i =0 ;i<16 ;i=i+1 ) begin
mem[i]<=0;
end
end
else if (soft_reset) begin
for (i =0 ;i<16 ;i=i+1 ) begin
mem[i]<=0;
end
end
else if(write_enb==1 && full==0)
begin
mem[wr_pntr]<={temp,data_in[7:0]};
end
else
mem[wr_pntr]<=mem[wr_pntr];
end
// read operation
always @(posedge clock) begin
if (!resetn) begin
data_out<=8'h00;
end
else if (soft_reset)
begin
data_out<=8'hz;
end
else
if(counter==6'b000000) begin
data_out<=9'bz;
end
else if(read_enb==1 && empty==0) begin
data_out<=mem[rd_pntr];
end
end
// counterer operation for full and empty
always @(posedge clock) begin
if (!resetn)
begin
f_e_count<=5'b00000;
end
else if (soft_reset)
begin
f_e_count<=5'b00000;
end
else
begin
case({write_enb,read_enb})
2'b10:if (f_e_count != DATA_DEPTH)
begin
f_e_count<=f_e_count+1;
end
2'b01:if (f_e_count != 5'b00000)
begin
f_e_count<=f_e_count-1;
end
2'b00:f_e_count<=f_e_count;
2'b11:f_e_count<=f_e_count;
default : f_e_count<=f_e_count;
endcase
end
end
always@(posedge clock)
begin
//check the msb value of data and if its 1 its a header and then take payload length+1 as count(1st bit for header; last 2 bits for address)
if(mem[rd_pntr][8] && read_enb && ~empty)
counter<=mem[rd_pntr][7:2]+1;
//decrement value until count becomes zero or until count is a non zero value
else if((counter!=0) && read_enb && ~empty)
counter<=counter-1;
else
counter<=counter;
end
endmodule

+ 142
- 0
RISC_V/NOC/router_fsm.v 查看文件

@@ -0,0 +1,142 @@
module router_fsm(input clock,resetn,pkt_valid,
input [1:0] data_in,
input fifo_full,fifo_empty_0,fifo_empty_1,fifo_empty_2,fifo_empty_3,soft_reset_0,soft_reset_1,soft_reset_2,soft_reset_3,parity_done, low_packet_valid,
output write_enb_reg,detect_add,ld_state,laf_state,lfd_state,full_state,rst_int_reg,busy);
parameter DECODE_ADDRESS = 4'b0001,
WAIT_TILL_EMPTY = 4'b0010,
LOAD_FIRST_DATA = 4'b0011,
LOAD_DATA = 4'b0100,
LOAD_PARITY = 4'b0101,
FIFO_FULL_STATE = 4'b0110,
LOAD_AFTER_FULL = 4'b0111,
CHECK_PARITY_ERROR = 4'b1000;
reg [3:0] present_state, next_state;
reg [1:0] temp;
wire temp_lfd_state;
//temp logic
always@(posedge clock)
begin
if(~resetn)
temp<=2'b0;
else if(detect_add == 2'b00 || 2'b01 || 2'b10 || 2'b11) // decides the address of out channel
temp<=data_in;
end
// reset logic for states
always@(posedge clock)
begin
if(!resetn)
present_state<=DECODE_ADDRESS; // hard reset
else if (((soft_reset_0) && (temp==2'b00)) || ((soft_reset_1) && (temp==2'b01)) || ((soft_reset_2) && (temp==2'b10)) || ((soft_reset_3) && (temp==2'b11))) //if there is soft_reset and also using same channel so we do here and opertion
present_state<=DECODE_ADDRESS;
else
present_state<=next_state;
end
//state machine logic
always@(*)
begin
case(present_state)
DECODE_ADDRESS: // decode address state
begin
if((pkt_valid && (data_in==2'b00) && fifo_empty_0)|| (pkt_valid && (data_in==2'b01) && fifo_empty_1)|| (pkt_valid && (data_in==2'b10) && fifo_empty_2) || (pkt_valid && (data_in==2'b11) && fifo_empty_3))
next_state<=LOAD_FIRST_DATA; //lfd_state
else if((pkt_valid && (data_in==2'b00) && !fifo_empty_0)||(pkt_valid && (data_in==2'b01) && !fifo_empty_1)||(pkt_valid && (data_in==2'b10) && !fifo_empty_2) || (pkt_valid && (data_in==2'b11) && !fifo_empty_3))
next_state<=WAIT_TILL_EMPTY; //wait till empty state
else
next_state<=DECODE_ADDRESS; // same state
end
LOAD_FIRST_DATA: // load first data state
begin
next_state<=LOAD_DATA;
end
WAIT_TILL_EMPTY: //wait till empty state
begin
if((fifo_empty_0 && (temp==2'b00))||(fifo_empty_1 && (temp==2'b01))||(fifo_empty_2 && (temp==2'b10)) || (fifo_empty_3 && (temp==2'b11))) //fifo is empty and were using same fifo
next_state<=LOAD_FIRST_DATA;
else
next_state<=WAIT_TILL_EMPTY;
end
LOAD_DATA: //load data
begin
if(fifo_full==1'b1)
next_state<=FIFO_FULL_STATE;
else
begin
if (!fifo_full && !pkt_valid)
next_state<=LOAD_PARITY;
else
next_state<=LOAD_DATA;
end
end
FIFO_FULL_STATE: //fifo full state
begin
if(fifo_full==0)
next_state<=LOAD_AFTER_FULL;
else
next_state<=FIFO_FULL_STATE;
end
LOAD_AFTER_FULL: // load after full state
begin
if(!parity_done && low_packet_valid)
next_state<=LOAD_PARITY;
else if(!parity_done && !low_packet_valid)
next_state<=LOAD_DATA;
else
begin
if(parity_done==1'b1)
next_state<=DECODE_ADDRESS;
else
next_state<=LOAD_AFTER_FULL;
end
end
LOAD_PARITY: // load parity state
begin
next_state<=CHECK_PARITY_ERROR;
end
CHECK_PARITY_ERROR: // check parity error
begin
if(!fifo_full)
next_state<=DECODE_ADDRESS;
else
next_state<=FIFO_FULL_STATE;
end
default: //default state
next_state<=DECODE_ADDRESS;
endcase // state machine completed
end
// output logic
assign detect_add=((present_state==DECODE_ADDRESS))?1:0;
assign busy=((present_state==LOAD_FIRST_DATA)||(present_state==LOAD_PARITY)||(present_state==FIFO_FULL_STATE)||(present_state==LOAD_AFTER_FULL)||(present_state==WAIT_TILL_EMPTY)||(present_state==CHECK_PARITY_ERROR))?1:0;
assign lfd_state=(temp_lfd_state)?1:0;
assign temp_lfd_state=((present_state==LOAD_FIRST_DATA))?1:0; //1 clock cycle delay
assign ld_state=((present_state==LOAD_DATA))?1:0;
assign write_enb_reg=((present_state==LOAD_DATA)||(present_state==LOAD_AFTER_FULL)||(present_state==LOAD_PARITY))?1:0;
assign full_state=((present_state==FIFO_FULL_STATE))?1:0;
assign laf_state=((present_state==LOAD_AFTER_FULL))?1:0;
assign rst_int_reg=((present_state==CHECK_PARITY_ERROR))?1:0;
endmodule

+ 119
- 0
RISC_V/NOC/router_reg.v 查看文件

@@ -0,0 +1,119 @@
module router_reg(data_out,err,parity_done,low_packet_valid,clock,resetn,pkt_valid,data_in,fifo_full,detect_add,ld_state,laf_state,full_state,lfd_state,rst_int_reg);
input clock,resetn,pkt_valid;
input [7:0]data_in;
input fifo_full,detect_add,ld_state,laf_state,full_state,lfd_state,rst_int_reg;
output reg err,parity_done,low_packet_valid;
output reg [7:0]data_out;
reg [7:0]header_byte,fifo_full_state,internal_parity,packet_parity;
//low_packet valid
always@(posedge clock)
begin
if(!resetn)
low_packet_valid<=1'b0;
else
begin
if(rst_int_reg)
low_packet_valid<=1'b0;
if(ld_state==1'b1 && pkt_valid==1'b0)
low_packet_valid<=1'b1;
end
end
//data_out
always@(posedge clock)
begin
if(!resetn)
data_out<=8'b0;
else
begin
if(detect_add && pkt_valid)
header_byte<=data_in;
else if(lfd_state)
data_out<=header_byte;
else if(ld_state && !fifo_full)
data_out<=data_in;
else if(ld_state && fifo_full)
fifo_full_state<=data_in;
else
begin
if(laf_state)
data_out<=fifo_full_state;
end
end
end
//parity done
always@(posedge clock)
begin
if(!resetn)
begin
parity_done<=1'b0;
end
else
begin
if(ld_state && !fifo_full && !pkt_valid)
parity_done<=1'b1;
else if(laf_state && low_packet_valid && !parity_done)
parity_done<=1'b1;
else
begin
if(detect_add)
parity_done<=1'b0;
end
end
end
// internal parity
always@(posedge clock)
begin
if(!resetn)
internal_parity<=8'b0;
else if(lfd_state)
internal_parity<=internal_parity ^ header_byte;
else if(ld_state && pkt_valid && !full_state)
internal_parity<=internal_parity ^ data_in;
else
begin
if (detect_add)
internal_parity<=8'b0;
end
end
//packet_parity
always@(posedge clock)
begin
if(!resetn)
packet_parity<=8'b0;
else
begin
if(!pkt_valid && ld_state)
packet_parity<=data_in;
end
end
//error
always@(posedge clock)
begin
if(!resetn)
err<=1'b0;
else
begin
if(parity_done)
begin
if(internal_parity!=packet_parity)
err<=1'b1;
else
err<=1'b0;
end
end
end
endmodule

+ 177
- 0
RISC_V/NOC/router_sync.v 查看文件

@@ -0,0 +1,177 @@
module router_sync(write_enb,fifo_full,vld_out_0,vld_out_1,vld_out_2,vld_out_3,soft_reset_0,soft_reset_1,soft_reset_2,soft_reset_3,clock,resetn,data_in,detect_add,full_0,full_1,full_2,full_3,empty_0,empty_1,empty_2,empty_3,write_enb_reg,read_enb_0,read_enb_1,read_enb_2,read_enb_3);
output reg [3:0]write_enb;
output vld_out_0,vld_out_1,vld_out_2,vld_out_3;
output reg fifo_full,soft_reset_0,soft_reset_1,soft_reset_2,soft_reset_3;
input [1:0]data_in;
input clock,resetn,detect_add,write_enb_reg;
input full_0,full_1,full_2,full_3,empty_0,empty_1,empty_2,empty_3,read_enb_0,read_enb_1,read_enb_2,read_enb_3;
reg [1:0]temp_data_in;
reg [5:0]count_0,count_1,count_2,count_3;
assign vld_out_0=~empty_0;
assign vld_out_1=~empty_1;
assign vld_out_2=~empty_2;
assign vld_out_3=~empty_3;
//data_in
always @(posedge clock) begin
if(!resetn) begin
temp_data_in<=2'b0;
end
else if (detect_add) begin
temp_data_in<= data_in;
end
end
//write enable
always @(*) begin
if (!resetn) begin
write_enb<=4'b0000;
end
else if(write_enb_reg)
begin
case(temp_data_in)
2'b00: write_enb=4'b0001;
2'b01: write_enb=4'b0010;
2'b10: write_enb=4'b0100;
2'b11: write_enb=4'b1000;
default write_enb=4'b0000;
endcase
end
else
write_enb=4'b0000;
end
//fifo operation
always @(*) begin
if(!resetn) begin
fifo_full=1'b0;
end
else
begin
case(temp_data_in)
2'b00: fifo_full=full_0;
2'b01: fifo_full=full_1;
2'b10: fifo_full=full_2;
2'b11: fifo_full=full_3;
default fifo_full=1'b0;
endcase
end
end
//soft reset counter
// counter 0
always@(posedge clock)
begin
if(!resetn)
count_0<=5'b0;
else if(vld_out_0)
begin
if(!read_enb_0)
begin
if(count_0==5'b11110)
begin
soft_reset_0<=1'b1;
count_0<=1'b0;
end
else
begin
count_0<=count_0+1'b1;
soft_reset_0<=1'b0;
end
end
else
count_0<=5'd0;
end
else
count_0<=5'd0;
end
//counter 1
always@(posedge clock)
begin
if(!resetn)
count_1<=5'b0;
else if(vld_out_1)
begin
if(!read_enb_1)
begin
if(count_1==5'b11110)
begin
soft_reset_1<=1'b1;
count_1<=1'b0;
end
else
begin
count_1<=count_1+1'b1;
soft_reset_1<=1'b0;
end
end
else
count_1<=5'd0;
end
else
count_1<=5'd0;
end
//counter 2
always@(posedge clock)
begin
if(!resetn)
count_2<=5'b0;
else if(vld_out_2)
begin
if(!read_enb_2)
begin
if(count_2==5'b11110)
begin
soft_reset_2<=1'b1;
count_2<=1'b0;
end
else
begin
count_2<=count_2+1'b1;
soft_reset_2<=1'b0;
end
end
else
count_2<=5'd0;
end
else
count_2<=5'd0;
end
//counter 3
always@(posedge clock)
begin
if(!resetn)
count_3<=5'b0;
else if(vld_out_3)
begin
if(!read_enb_3)
begin
if(count_3==5'b11110)
begin
soft_reset_3<=1'b1;
count_3<=1'b0;
end
else
begin
count_3<=count_3+1'b1;
soft_reset_3<=1'b0;
end
end
else
count_3<=5'd0;
end
else
count_3<=5'd0;
end
endmodule

+ 36
- 0
RISC_V/NOC/router_top.v 查看文件

@@ -0,0 +1,36 @@
module router_top(data_out_0,data_out_1,data_out_2,data_out_3,vld_out_0,vld_out_1,vld_out_2,vld_out_3,error,busy,clock,resetn,read_enb_0,read_enb_1,read_enb_2,read_enb_3,data_in,pkt_valid);
output [7:0] data_out_0,data_out_1,data_out_2,data_out_3;
output vld_out_0,vld_out_1,vld_out_2,vld_out_3,error,busy;
input clock,resetn,read_enb_0,read_enb_1,read_enb_2,read_enb_3,pkt_valid;
input [7:0] data_in;
wire [7:0] data_in_out;
wire [3:0] write_enb;
// Instantiating sub-modules
// FIFO-0
router_fifo FIFO_0(data_out_0,full_0,fifo_empty_0,clock,resetn,soft_reset_0,data_in_out,write_enb[0],read_enb_0,lfd_state);
//FIFO-1
router_fifo FIFO_1(data_out_1,full_1,fifo_empty_1,clock,resetn,soft_reset_1,data_in_out,write_enb[1],read_enb_1,lfd_state);
//FIFO-2
router_fifo FIFO_2(data_out_2,full_2,fifo_empty_2,clock,resetn,soft_reset_2,data_in_out,write_enb[2],read_enb_2,lfd_state);
//FIFO-3
router_fifo FIFO_3(data_out_3,full_3,fifo_empty_3,clock,resetn,soft_reset_3,data_in_out,write_enb[3],read_enb_3,lfd_state);
// Synchronizer
router_sync SYNC(write_enb,fifo_full,vld_out_0,vld_out_1,vld_out_2,vld_out_3,soft_reset_0,soft_reset_1,soft_reset_2,soft_reset_3,clock,resetn,data_in[1:0],detect_add,full_0,full_1,full_2,full_3,fifo_empty_0,fifo_empty_1,fifo_empty_2,fifo_empty_3,write_enb_reg,read_enb_0,read_enb_1,read_enb_2,read_enb_3);
//FSM controller
router_fsm FSM(clock,resetn,pkt_valid,data_in[1:0],fifo_full,fifo_empty_0,fifo_empty_1,fifo_empty_2,fifo_empty_3,soft_reset_0,soft_reset_1,soft_reset_2,soft_reset_3,parity_done, low_packet_valid,write_enb_reg,detect_add,ld_state,laf_state,lfd_state,full_state,rst_int_reg,busy);
//Register
router_reg REG(data_in_out,error,parity_done,low_packet_valid,clock,resetn,pkt_valid,data_in,fifo_full,detect_add,ld_state,laf_state,full_state,lfd_state,rst_int_reg);
endmodule

+ 123
- 0
RISC_V/NOC/router_top_tb.v 查看文件

@@ -0,0 +1,123 @@
module router_top_tb();
reg clock,resetn,read_enb_0,read_enb_1,read_enb_2,read_enb_3,pkt_valid;
reg [7:0] data_in;
wire [7:0]data_out_0,data_out_1,data_out_2,data_out_3;
wire vld_out_0,vld_out_1,vld_out_2,vld_out_3,error,busy;
integer i;
router_top DUT(data_out_0,data_out_1,data_out_2,data_out_3,vld_out_0,vld_out_1,vld_out_2,vld_out_3,error,busy,clock,resetn,read_enb_0,read_enb_1,read_enb_2,read_enb_3,data_in,pkt_valid);
always begin
clock=1'b0;
forever #5 clock=~clock;
end
task resetnip;
begin
@(negedge clock);
resetn=1'b0;
@(negedge clock);
resetn=1'b1;
end
endtask
task packet_gen_14;
reg [7:0]payload_data,parity,header;
reg [5:0]payload_len;
reg [1:0]addr;
begin
@(negedge clock);
payload_len=6'd14;
addr=2'b00; // valid packet
header={payload_len,addr};
parity=0;
data_in=header;
pkt_valid=1;
parity=parity^header;
@(negedge clock);
wait(~busy)
for (i =0;i<payload_len ;i=i+1 ) begin
@(negedge clock);
wait(~busy)
payload_data={$random}%256;
data_in=payload_data;
parity=parity^payload_data;
end
@(negedge clock);
wait(~busy)
pkt_valid=0;
data_in=parity;
end
endtask
task packet_gen_16;
reg [7:0]payload_data,parity,header;
reg [5:0]payload_len;
reg [1:0]addr;
begin
@(negedge clock);
payload_len=6'd16;
addr=2'b11; // valid packet
header={payload_len,addr};
parity=0;
data_in=header;
pkt_valid=1;
parity=parity^header;
@(negedge clock);
wait(~busy)
for (i =0;i<payload_len ;i=i+1 ) begin
@(negedge clock);
wait(~busy)
payload_data={$random}%256;
data_in=payload_data;
parity=parity^payload_data;
end
@(negedge clock);
wait(~busy)
pkt_valid=0;
data_in=parity;
end
endtask
initial begin
resetnip;
read_enb_0=1'b0;
read_enb_1=1'b0;
read_enb_2=1'b0;
read_enb_3=1'b0;
#10;
packet_gen_14;
#10;
read_enb_0=1'b1;
#180;
read_enb_0=1'b0;
read_enb_1=1'b0;
read_enb_2=1'b0;
read_enb_3=1'b0;
#10;
packet_gen_16;
#10;
read_enb_3=1'b1;
#200;
resetnip;
end
initial begin
#800 $finish;
end
initial begin
$monitor("resetn = %d ,read_enb_0 = %d ,read_enb_1 = %d ,read_enb_2 = %d ,pkt_valid = %d ,data_in = %d ,data_out_0 = %d ,data_out_1 = %d ,data_out_2 = %d ,vld_out_0 = %d ,vld_out_1 = %d ,vld_out_2 = %d ,error = %d ,busy = %d",resetn,read_enb_0,read_enb_1,read_enb_2,pkt_valid,data_in,data_out_0,data_out_1,data_out_2,vld_out_0,vld_out_1,vld_out_2,error,busy);
end
endmodule

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