// *************************************************************************** // *************************************************************************** // Copyright (C) 2014-2023 Analog Devices, Inc. All rights reserved. // // In this HDL repository, there are many different and unique modules, consisting // of various HDL (Verilog or VHDL) components. The individual modules are // developed independently, and may be accompanied by separate and unique license // terms. // // The user should read each of these license terms, and understand the // freedoms and responsibilities that he or she has by using this source/core. // // This core is distributed in the hope that it will be useful, but WITHOUT ANY // WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR // A PARTICULAR PURPOSE. // // Redistribution and use of source or resulting binaries, with or without modification // of this file, are permitted under one of the following two license terms: // // 1. The GNU General Public License version 2 as published by the // Free Software Foundation, which can be found in the top level directory // of this repository (LICENSE_GPL2), and also online at: // // // OR // // 2. An ADI specific BSD license, which can be found in the top level directory // of this repository (LICENSE_ADIBSD), and also on-line at: // https://github.com/analogdevicesinc/hdl/blob/master/LICENSE_ADIBSD // This will allow to generate bit files and not release the source code, // as long as it attaches to an ADI device. // // *************************************************************************** // *************************************************************************** `timescale 1ns/1ps module avl_adxcfg #( parameter ADDRESS_WIDTH = 10 ) ( // reconfig sharing input rcfg_clk, input rcfg_reset_n, input rcfg_in_read_0, input rcfg_in_write_0, input [ADDRESS_WIDTH-1:0] rcfg_in_address_0, input [31:0] rcfg_in_writedata_0, output [31:0] rcfg_in_readdata_0, output rcfg_in_waitrequest_0, input rcfg_in_read_1, input rcfg_in_write_1, input [ADDRESS_WIDTH-1:0] rcfg_in_address_1, input [31:0] rcfg_in_writedata_1, output [31:0] rcfg_in_readdata_1, output rcfg_in_waitrequest_1, output rcfg_out_read_0, output rcfg_out_write_0, output [ADDRESS_WIDTH-1:0] rcfg_out_address_0, output [31:0] rcfg_out_writedata_0, input [31:0] rcfg_out_readdata_0, input rcfg_out_waitrequest_0, output rcfg_out_read_1, output rcfg_out_write_1, output [ADDRESS_WIDTH-1:0] rcfg_out_address_1, output [31:0] rcfg_out_writedata_1, input [31:0] rcfg_out_readdata_1, input rcfg_out_waitrequest_1 ); // internal registers reg [ 1:0] rcfg_select = 'd0; reg rcfg_read_int = 'd0; reg rcfg_write_int = 'd0; reg [ADDRESS_WIDTH-1:0] rcfg_address_int = 'd0; reg [31:0] rcfg_writedata_int = 'd0; reg [31:0] rcfg_readdata_int = 'd0; reg rcfg_waitrequest_int_0 = 'd1; reg rcfg_waitrequest_int_1 = 'd1; // internal signals wire [31:0] rcfg_readdata_s; wire rcfg_waitrequest_s; // xcvr sharing requires same bus (sw must make sure they are mutually exclusive access). assign rcfg_out_read_0 = rcfg_read_int; assign rcfg_out_write_0 = rcfg_write_int; assign rcfg_out_address_0 = rcfg_address_int; assign rcfg_out_writedata_0 = rcfg_writedata_int; assign rcfg_out_read_1 = rcfg_read_int; assign rcfg_out_write_1 = rcfg_write_int; assign rcfg_out_address_1 = rcfg_address_int; assign rcfg_out_writedata_1 = rcfg_writedata_int; assign rcfg_in_readdata_0 = rcfg_readdata_int; assign rcfg_in_readdata_1 = rcfg_readdata_int; assign rcfg_in_waitrequest_0 = rcfg_waitrequest_int_0; assign rcfg_in_waitrequest_1 = rcfg_waitrequest_int_1; assign rcfg_readdata_s = rcfg_out_readdata_1 & rcfg_out_readdata_0; assign rcfg_waitrequest_s = rcfg_out_waitrequest_1 & rcfg_out_waitrequest_0; always @(negedge rcfg_reset_n or posedge rcfg_clk) begin if (rcfg_reset_n == 0) begin rcfg_select <= 2'd0; rcfg_read_int <= 1'd0; rcfg_write_int <= 1'd0; rcfg_address_int <= 'd0; rcfg_writedata_int <= 32'd0; rcfg_readdata_int <= 32'd0; rcfg_waitrequest_int_0 <= 1'b1; rcfg_waitrequest_int_1 <= 1'b1; end else begin if (rcfg_select[1] == 1'b1) begin if (rcfg_waitrequest_s == 1'b0) begin rcfg_select <= 2'd0; rcfg_read_int <= 1'b0; rcfg_write_int <= 1'b0; rcfg_address_int <= 'd0; rcfg_writedata_int <= 32'd0; end rcfg_readdata_int <= rcfg_readdata_s; rcfg_waitrequest_int_0 <= rcfg_waitrequest_s | rcfg_select[0]; rcfg_waitrequest_int_1 <= rcfg_waitrequest_s | ~rcfg_select[0]; end else if ((rcfg_in_read_0 == 1'b1) || (rcfg_in_write_0 == 1'b1)) begin rcfg_select <= 2'b10; rcfg_read_int <= rcfg_in_read_0; rcfg_write_int <= rcfg_in_write_0; rcfg_address_int <= rcfg_in_address_0; rcfg_writedata_int <= rcfg_in_writedata_0; rcfg_readdata_int <= 32'd0; rcfg_waitrequest_int_0 <= 1'b1; rcfg_waitrequest_int_1 <= 1'b1; end else if ((rcfg_in_read_1 == 1'b1) || (rcfg_in_write_1 == 1'b1)) begin rcfg_select <= 2'b11; rcfg_read_int <= rcfg_in_read_1; rcfg_write_int <= rcfg_in_write_1; rcfg_address_int <= rcfg_in_address_1; rcfg_writedata_int <= rcfg_in_writedata_1; rcfg_readdata_int <= 32'd0; rcfg_waitrequest_int_0 <= 1'b1; rcfg_waitrequest_int_1 <= 1'b1; end else begin rcfg_select <= 2'd0; rcfg_read_int <= 1'd0; rcfg_write_int <= 1'd0; rcfg_address_int <= 'd0; rcfg_writedata_int <= 32'd0; rcfg_readdata_int <= 32'd0; rcfg_waitrequest_int_0 <= 1'b1; rcfg_waitrequest_int_1 <= 1'b1; end end end endmodule