Hi ,
I have customize IP which integrated with AXI bus using up_axi.v as memory mapping . It' similar approach like axi_ad961 IP . I have updated address width as 32 bits as below. Actually my design write/read address use 16 bits only .
I found AD9361 IP Reg Address are 0x0000, 0x0004, 0x0008 etc..
up_raddr <= up_axi_araddr[AW+2:2]; //original axi bus address define from github
up_wdata <= up_axi_wdata; // Updated for my design
I also used axi_vip IP to verify for AXI bus connection with my design . The simulation results for write / read data is working .
I have Attached simulation picture here. My simulation testbench is using direct address bus mean base address plus my FPGA reg address.
If our software write / read reg bus address , the address need to be multiple by 4 or can use direct base address plus write_reg address. I have attached my version of up_axi.v .
When software try to write address multiple by 4 then , the read back reg bus data is incorrect . Software require to write like 8000_9004 then , can able to read back for
16 bits data . 8000_0000 is my base address and 9004 is my read reg address.
I would like to understand how to adapt up_axi.v to my 16bit write /read reg address bus design . How the software should write address like need to be 4 bytes align or direct address .
Could you help to take a look for
`timescale 1ns/100ps
module up_axi (
// reset and clocks
up_rstn,
up_clk,
// axi4 interface
up_axi_awvalid,
up_axi_awaddr,
up_axi_awready,
/////////////////////////////////////////////////////
up_axi_wvalid,
up_axi_wdata,
up_axi_wstrb,
up_axi_wready,
/////////////////////////////////////////////////////
up_axi_bvalid,
up_axi_bresp,
up_axi_bready,
/////////////////////////////////////////////////////
up_axi_arvalid,
up_axi_araddr,
up_axi_arready,
/////////////////////////////////////////////////////
up_axi_rvalid,
up_axi_rresp,
up_axi_rdata,
up_axi_rready,
// pcore interface
up_wreq,
up_waddr,
up_wdata,
up_wack,
up_rreq,
up_raddr,
up_rdata,
up_rack);
// parameters
parameter ADDRESS_WIDTH = 14;
//parameter ADDRESS_WIDTH = 16;
localparam AW = ADDRESS_WIDTH - 1;
// reset and clocks
input up_rstn;
input up_clk;
// axi4 interface
input up_axi_awvalid;
input [31:0] up_axi_awaddr;
output up_axi_awready;
input up_axi_wvalid;
input [31:0] up_axi_wdata;
input [ 3:0] up_axi_wstrb;
output up_axi_wready;
output up_axi_bvalid;
output [ 1:0] up_axi_bresp;
input up_axi_bready;
input up_axi_arvalid;
input [31:0] up_axi_araddr;
output up_axi_arready;
output up_axi_rvalid;
output [ 1:0] up_axi_rresp;
output [31:0] up_axi_rdata;
input up_axi_rready;
// pcore interface
output up_wreq;
//output [AW:0] up_waddr;
output [31:0] up_waddr;
output [31:0] up_wdata;
input up_wack;
output up_rreq;
//output [AW:0] up_raddr;
output [31:0] up_raddr;
input [31:0] up_rdata;
input up_rack;
// internal registers
reg up_axi_awready = 'd0;
reg up_axi_wready = 'd0;
reg up_axi_bvalid = 'd0;
reg up_wsel = 'd0;
reg up_wreq = 'd0;
//reg [AW:0] up_waddr = 'd0;
reg [31:0] up_waddr = 'd0;
reg [31:0] up_wdata = 'd0;
reg [ 2:0] up_wcount = 'd0;
reg up_wack_int = 'd0;
reg up_axi_arready = 'd0;
reg up_axi_rvalid = 'd0;
reg [31:0] up_axi_rdata = 'd0;
reg up_rsel = 'd0;
reg up_rreq = 'd0;
reg [31:0] up_raddr = 'd0;
//reg [AW:0] up_raddr = 'd0;
reg [ 3:0] up_rcount = 'd0;
reg up_rack_int = 'd0;
reg [31:0] up_rdata_int = 'd0;
reg up_rack_int_d = 'd0;
reg [31:0] up_rdata_int_d = 'd0;
// write channel interface
assign up_axi_bresp = 2'd0;
always @(negedge up_rstn or posedge up_clk) begin
if (up_rstn == 1'b0) begin
up_axi_awready <= 'd0;
up_axi_wready <= 'd0;
up_axi_bvalid <= 'd0;
end else begin
if (up_axi_awready == 1'b1) begin
up_axi_awready <= 1'b0;
end else if (up_wack_int == 1'b1) begin
up_axi_awready <= 1'b1;
end
if (up_axi_wready == 1'b1) begin
up_axi_wready <= 1'b0;
end else if (up_wack_int == 1'b1) begin
up_axi_wready <= 1'b1;
end
if ((up_axi_bready == 1'b1) && (up_axi_bvalid == 1'b1)) begin
up_axi_bvalid <= 1'b0;
end else if (up_wack_int == 1'b1) begin
up_axi_bvalid <= 1'b1;
end
end
end
always @(negedge up_rstn or posedge up_clk) begin
if (up_rstn == 1'b0) begin
up_wsel <= 'd0;
up_wreq <= 'd0;
up_waddr <= 'd0;
up_wdata <= 'd0;
up_wcount <= 'd0;
end else begin
if (up_wsel == 1'b1) begin
if ((up_axi_bready == 1'b1) && (up_axi_bvalid == 1'b1)) begin
up_wsel <= 1'b0;
end
up_wreq <= 1'b0;
up_waddr <= up_waddr;
up_wdata <= up_wdata;
up_wcount <= up_wcount + 1'b1;
end else begin
up_wsel <= up_axi_awvalid & up_axi_wvalid;
up_wreq <= up_axi_awvalid & up_axi_wvalid;
up_waddr <= up_axi_awaddr;
//up_waddr <= up_axi_awaddr[AW+2:2];
up_wdata <= up_axi_wdata;
up_wcount <= 3'd0;
end
end
end
always @(negedge up_rstn or posedge up_clk) begin
if (up_rstn == 0) begin
up_wack_int <= 'd0;
end else begin
if ((up_wcount == 3'h7) && (up_wack == 1'b0)) begin
up_wack_int <= 1'b1;
end else if (up_wsel == 1'b1) begin
up_wack_int <= up_wack;
end
end
end
// read channel interface
assign up_axi_rresp = 2'd0;
always @(negedge up_rstn or posedge up_clk) begin
if (up_rstn == 1'b0) begin
up_axi_arready <= 'd0;
up_axi_rvalid <= 'd0;
up_axi_rdata <= 'd0;
end else begin
if (up_axi_arready == 1'b1) begin
up_axi_arready <= 1'b0;
end else if (up_rack_int == 1'b1) begin
up_axi_arready <= 1'b1;
end
if ((up_axi_rready == 1'b1) && (up_axi_rvalid == 1'b1)) begin
up_axi_rvalid <= 1'b0;
up_axi_rdata <= 32'd0;
end else if (up_rack_int_d == 1'b1) begin
up_axi_rvalid <= 1'b1;
up_axi_rdata <= up_rdata_int_d;
end
end
end
always @(negedge up_rstn or posedge up_clk) begin
if (up_rstn == 1'b0) begin
up_rsel <= 'd0;
up_rreq <= 'd0;
up_raddr <= 'd0;
up_rcount <= 'd0;
end else begin
if (up_rsel == 1'b1) begin
if ((up_axi_rready == 1'b1) && (up_axi_rvalid == 1'b1)) begin
up_rsel <= 1'b0;
end
up_rreq <= 1'b0;
up_raddr <= up_raddr;
end else begin
up_rsel <= up_axi_arvalid;
up_rreq <= up_axi_arvalid;
//up_raddr <= up_axi_araddr[AW+2:2];
up_raddr <= up_axi_araddr;
end
if (up_rack_int == 1'b1) begin
up_rcount <= 4'd0;
end else if (up_rcount[3] == 1'b1) begin
up_rcount <= up_rcount + 1'b1;
end else if (up_rreq == 1'b1) begin
up_rcount <= 4'd8;
end
end
end
always @(negedge up_rstn or posedge up_clk) begin
if (up_rstn == 0) begin
up_rack_int <= 'd0;
up_rdata_int <= 'd0;
up_rack_int_d <= 'd0;
up_rdata_int_d <= 'd0;
end else begin
if ((up_rcount == 4'hf) && (up_rack == 1'b0)) begin
up_rack_int <= 1'b1;
up_rdata_int <= {2{16'hdead}};
end else begin
up_rack_int <= up_rack;
up_rdata_int <= up_rdata;
end
up_rack_int_d <= up_rack_int;
up_rdata_int_d <= up_rdata_int;
end
end
endmodule
// ***************************************************************************
// ***************************************************************************
this ? Thank you so much for your help.
Appreciate for your reply.