///////////////////////////////////////////////////////////////////// //// //// //// WISHBONE Connection Bus Top Level //// //// //// //// //// //// Original Author: Johny Chi //// //// chisuhua@yahoo.com.cn //// //// Modified By Matt Ettus, matt@ettus.com //// //// //// //// //// ///////////////////////////////////////////////////////////////////// //// //// //// Copyright (C) 2000, 2007 Authors and OPENCORES.ORG //// //// //// //// This source file may be used and distributed without //// //// restriction provided that this copyright statement is not //// //// removed from the file and that any derivative work contains //// //// the original copyright notice and the associated disclaimer. //// //// //// //// This source file is free software; you can redistribute it //// //// and/or modify it under the terms of the GNU Lesser General //// //// Public License as published by the Free Software Foundation; //// //// either version 2.1 of the License, or (at your option) any //// //// later version. //// //// //// //// This source 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. See the GNU Lesser General Public License for more //// //// details. //// //// //// //// You should have received a copy of the GNU Lesser General //// //// Public License along with this source; if not, download it //// //// from http://www.opencores.org/lgpl.shtml //// //// //// ////////////////////////////////////////////////////////////////////// // // Up to 8 slaves share a Wishbone Bus connection to 1 master module wb_1master #(parameter s0_addr_w = 4, // slave 0 address decode width parameter s0_addr = 4'h0, // slave 0 address parameter s1_addr_w = 4 , // slave 1 address decode width parameter s1_addr = 4'h1, // slave 1 address parameter s215_addr_w = 8 , // slave 2 to slave 7 address decode width parameter s2_addr = 8'h92, // slave 2 address parameter s3_addr = 8'h93, // slave 3 address parameter s4_addr = 8'h94, // slave 4 address parameter s5_addr = 8'h95, // slave 5 address parameter s6_addr = 8'h96, // slave 6 address parameter s7_addr = 8'h97, // slave 7 address parameter s8_addr = 8'h98, // slave 7 address parameter s9_addr = 8'h99, // slave 7 address parameter s10_addr = 8'h9a, // slave 7 address parameter s11_addr = 8'h9b, // slave 7 address parameter s12_addr = 8'h9c, // slave 7 address parameter s13_addr = 8'h9d, // slave 7 address parameter s14_addr = 8'h9e, // slave 7 address parameter s15_addr = 8'h9f, // slave 7 address parameter dw = 32, // Data bus Width parameter aw = 32, // Address bus Width parameter sw = 4) // Number of Select Lines (input clk_i, input rst_i, // Master Interface input [dw-1:0] m0_dat_i, output [dw-1:0] m0_dat_o, input [aw-1:0] m0_adr_i, input [sw-1:0] m0_sel_i, input m0_we_i, input m0_cyc_i, input m0_stb_i, output m0_ack_o, output m0_err_o, output m0_rty_o, // Slave Interfaces input [dw-1:0] s0_dat_i, output [dw-1:0] s0_dat_o, output [aw-1:0] s0_adr_o, output [sw-1:0] s0_sel_o, output s0_we_o, output s0_cyc_o, output s0_stb_o, input s0_ack_i, input s0_err_i, input s0_rty_i, input [dw-1:0] s1_dat_i, output [dw-1:0] s1_dat_o, output [aw-1:0] s1_adr_o, output [sw-1:0] s1_sel_o, output s1_we_o, output s1_cyc_o, output s1_stb_o, input s1_ack_i, input s1_err_i, input s1_rty_i, input [dw-1:0] s2_dat_i, output [dw-1:0] s2_dat_o, output [aw-1:0] s2_adr_o, output [sw-1:0] s2_sel_o, output s2_we_o, output s2_cyc_o, output s2_stb_o, input s2_ack_i, input s2_err_i, input s2_rty_i, input [dw-1:0] s3_dat_i, output [dw-1:0] s3_dat_o, output [aw-1:0] s3_adr_o, output [sw-1:0] s3_sel_o, output s3_we_o, output s3_cyc_o, output s3_stb_o, input s3_ack_i, input s3_err_i, input s3_rty_i, input [dw-1:0] s4_dat_i, output [dw-1:0] s4_dat_o, output [aw-1:0] s4_adr_o, output [sw-1:0] s4_sel_o, output s4_we_o, output s4_cyc_o, output s4_stb_o, input s4_ack_i, input s4_err_i, input s4_rty_i, input [dw-1:0] s5_dat_i, output [dw-1:0] s5_dat_o, output [aw-1:0] s5_adr_o, output [sw-1:0] s5_sel_o, output s5_we_o, output s5_cyc_o, output s5_stb_o, input s5_ack_i, input s5_err_i, input s5_rty_i, input [dw-1:0] s6_dat_i, output [dw-1:0] s6_dat_o, output [aw-1:0] s6_adr_o, output [sw-1:0] s6_sel_o, output s6_we_o, output s6_cyc_o, output s6_stb_o, input s6_ack_i, input s6_err_i, input s6_rty_i, input [dw-1:0] s7_dat_i, output [dw-1:0] s7_dat_o, output [aw-1:0] s7_adr_o, output [sw-1:0] s7_sel_o, output s7_we_o, output s7_cyc_o, output s7_stb_o, input s7_ack_i, input s7_err_i, input s7_rty_i, input [dw-1:0] s8_dat_i, output [dw-1:0] s8_dat_o, output [aw-1:0] s8_adr_o, output [sw-1:0] s8_sel_o, output s8_we_o, output s8_cyc_o, output s8_stb_o, input s8_ack_i, input s8_err_i, input s8_rty_i, input [dw-1:0] s9_dat_i, output [dw-1:0] s9_dat_o, output [aw-1:0] s9_adr_o, output [sw-1:0] s9_sel_o, output s9_we_o, output s9_cyc_o, output s9_stb_o, input s9_ack_i, input s9_err_i, input s9_rty_i, input [dw-1:0] s10_dat_i, output [dw-1:0] s10_dat_o, output [aw-1:0] s10_adr_o, output [sw-1:0] s10_sel_o, output s10_we_o, output s10_cyc_o, output s10_stb_o, input s10_ack_i, input s10_err_i, input s10_rty_i, input [dw-1:0] s11_dat_i, output [dw-1:0] s11_dat_o, output [aw-1:0] s11_adr_o, output [sw-1:0] s11_sel_o, output s11_we_o, output s11_cyc_o, output s11_stb_o, input s11_ack_i, input s11_err_i, input s11_rty_i, input [dw-1:0] s12_dat_i, output [dw-1:0] s12_dat_o, output [aw-1:0] s12_adr_o, output [sw-1:0] s12_sel_o, output s12_we_o, output s12_cyc_o, output s12_stb_o, input s12_ack_i, input s12_err_i, input s12_rty_i, input [dw-1:0] s13_dat_i, output [dw-1:0] s13_dat_o, output [aw-1:0] s13_adr_o, output [sw-1:0] s13_sel_o, output s13_we_o, output s13_cyc_o, output s13_stb_o, input s13_ack_i, input s13_err_i, input s13_rty_i, input [dw-1:0] s14_dat_i, output [dw-1:0] s14_dat_o, output [aw-1:0] s14_adr_o, output [sw-1:0] s14_sel_o, output s14_we_o, output s14_cyc_o, output s14_stb_o, input s14_ack_i, input s14_err_i, input s14_rty_i, input [dw-1:0] s15_dat_i, output [dw-1:0] s15_dat_o, output [aw-1:0] s15_adr_o, output [sw-1:0] s15_sel_o, output s15_we_o, output s15_cyc_o, output s15_stb_o, input s15_ack_i, input s15_err_i, input s15_rty_i ); // //////////////////////////////////////////////////////////////// // // Local wires // wire [15:0] ssel_dec; reg [dw-1:0] i_dat_s; // internal share bus , slave data to master // Master output Interface assign m0_dat_o = i_dat_s; always @* case(ssel_dec) 1 : i_dat_s <= s0_dat_i; 2 : i_dat_s <= s1_dat_i; 4 : i_dat_s <= s2_dat_i; 8 : i_dat_s <= s3_dat_i; 16 : i_dat_s <= s4_dat_i; 32 : i_dat_s <= s5_dat_i; 64 : i_dat_s <= s6_dat_i; 128 : i_dat_s <= s7_dat_i; 256 : i_dat_s <= s8_dat_i; 512 : i_dat_s <= s9_dat_i; 1024 : i_dat_s <= s10_dat_i; 2048 : i_dat_s <= s11_dat_i; 4096 : i_dat_s <= s12_dat_i; 8192 : i_dat_s <= s13_dat_i; 16384 : i_dat_s <= s14_dat_i; 32768 : i_dat_s <= s15_dat_i; default : i_dat_s <= s0_dat_i; endcase // case(ssel_dec) assign {m0_ack_o, m0_err_o, m0_rty_o} = {s0_ack_i | s1_ack_i | s2_ack_i | s3_ack_i | s4_ack_i | s5_ack_i | s6_ack_i | s7_ack_i | s8_ack_i | s9_ack_i | s10_ack_i | s11_ack_i | s12_ack_i | s13_ack_i | s14_ack_i | s15_ack_i , s0_err_i | s1_err_i | s2_err_i | s3_err_i | s4_err_i | s5_err_i | s6_err_i | s7_err_i | s8_err_i | s9_err_i | s10_err_i | s11_err_i | s12_err_i | s13_err_i | s14_err_i | s15_err_i , s0_rty_i | s1_rty_i | s2_rty_i | s3_rty_i | s4_rty_i | s5_rty_i | s6_rty_i | s7_rty_i | s8_rty_i | s9_rty_i | s10_rty_i | s11_rty_i | s12_rty_i | s13_rty_i | s14_rty_i | s15_rty_i }; // Slave output interfaces assign s0_adr_o = m0_adr_i; assign s0_sel_o = m0_sel_i; assign s0_dat_o = m0_dat_i; assign s0_we_o = m0_we_i; assign s0_cyc_o = m0_cyc_i; assign s0_stb_o = m0_cyc_i & m0_stb_i & ssel_dec[0]; assign s1_adr_o = m0_adr_i; assign s1_sel_o = m0_sel_i; assign s1_dat_o = m0_dat_i; assign s1_we_o = m0_we_i; assign s1_cyc_o = m0_cyc_i; assign s1_stb_o = m0_cyc_i & m0_stb_i & ssel_dec[1]; assign s2_adr_o = m0_adr_i; assign s2_sel_o = m0_sel_i; assign s2_dat_o = m0_dat_i; assign s2_we_o = m0_we_i; assign s2_cyc_o = m0_cyc_i; assign s2_stb_o = m0_cyc_i & m0_stb_i & ssel_dec[2]; assign s3_adr_o = m0_adr_i; assign s3_sel_o = m0_sel_i; assign s3_dat_o = m0_dat_i; assign s3_we_o = m0_we_i; assign s3_cyc_o = m0_cyc_i; assign s3_stb_o = m0_cyc_i & m0_stb_i & ssel_dec[3]; assign s4_adr_o = m0_adr_i; assign s4_sel_o = m0_sel_i; assign s4_dat_o = m0_dat_i; assign s4_we_o = m0_we_i; assign s4_cyc_o = m0_cyc_i; assign s4_stb_o = m0_cyc_i & m0_stb_i & ssel_dec[4]; assign s5_adr_o = m0_adr_i; assign s5_sel_o = m0_sel_i; assign s5_dat_o = m0_dat_i; assign s5_we_o = m0_we_i; assign s5_cyc_o = m0_cyc_i; assign s5_stb_o = m0_cyc_i & m0_stb_i & ssel_dec[5]; assign s6_adr_o = m0_adr_i; assign s6_sel_o = m0_sel_i; assign s6_dat_o = m0_dat_i; assign s6_we_o = m0_we_i; assign s6_cyc_o = m0_cyc_i; assign s6_stb_o = m0_cyc_i & m0_stb_i & ssel_dec[6]; assign s7_adr_o = m0_adr_i; assign s7_sel_o = m0_sel_i; assign s7_dat_o = m0_dat_i; assign s7_we_o = m0_we_i; assign s7_cyc_o = m0_cyc_i; assign s7_stb_o = m0_cyc_i & m0_stb_i & ssel_dec[7]; assign s8_adr_o = m0_adr_i; assign s8_sel_o = m0_sel_i; assign s8_dat_o = m0_dat_i; assign s8_we_o = m0_we_i; assign s8_cyc_o = m0_cyc_i; assign s8_stb_o = m0_cyc_i & m0_stb_i & ssel_dec[8]; assign s9_adr_o = m0_adr_i; assign s9_sel_o = m0_sel_i; assign s9_dat_o = m0_dat_i; assign s9_we_o = m0_we_i; assign s9_cyc_o = m0_cyc_i; assign s9_stb_o = m0_cyc_i & m0_stb_i & ssel_dec[9]; assign s10_adr_o = m0_adr_i; assign s10_sel_o = m0_sel_i; assign s10_dat_o = m0_dat_i; assign s10_we_o = m0_we_i; assign s10_cyc_o = m0_cyc_i; assign s10_stb_o = m0_cyc_i & m0_stb_i & ssel_dec[10]; assign s11_adr_o = m0_adr_i; assign s11_sel_o = m0_sel_i; assign s11_dat_o = m0_dat_i; assign s11_we_o = m0_we_i; assign s11_cyc_o = m0_cyc_i; assign s11_stb_o = m0_cyc_i & m0_stb_i & ssel_dec[11]; assign s12_adr_o = m0_adr_i; assign s12_sel_o = m0_sel_i; assign s12_dat_o = m0_dat_i; assign s12_we_o = m0_we_i; assign s12_cyc_o = m0_cyc_i; assign s12_stb_o = m0_cyc_i & m0_stb_i & ssel_dec[12]; assign s13_adr_o = m0_adr_i; assign s13_sel_o = m0_sel_i; assign s13_dat_o = m0_dat_i; assign s13_we_o = m0_we_i; assign s13_cyc_o = m0_cyc_i; assign s13_stb_o = m0_cyc_i & m0_stb_i & ssel_dec[13]; assign s14_adr_o = m0_adr_i; assign s14_sel_o = m0_sel_i; assign s14_dat_o = m0_dat_i; assign s14_we_o = m0_we_i; assign s14_cyc_o = m0_cyc_i; assign s14_stb_o = m0_cyc_i & m0_stb_i & ssel_dec[14]; assign s15_adr_o = m0_adr_i; assign s15_sel_o = m0_sel_i; assign s15_dat_o = m0_dat_i; assign s15_we_o = m0_we_i; assign s15_cyc_o = m0_cyc_i; assign s15_stb_o = m0_cyc_i & m0_stb_i & ssel_dec[15]; // Address decode logic // WARNING -- must make sure these are mutually exclusive! assign ssel_dec[0] = (m0_adr_i[aw -1 : aw - s0_addr_w ] == s0_addr); assign ssel_dec[1] = (m0_adr_i[aw -1 : aw - s1_addr_w ] == s1_addr); assign ssel_dec[2] = (m0_adr_i[aw -1 : aw - s215_addr_w ] == s2_addr); assign ssel_dec[3] = (m0_adr_i[aw -1 : aw - s215_addr_w ] == s3_addr); assign ssel_dec[4] = (m0_adr_i[aw -1 : aw - s215_addr_w ] == s4_addr); assign ssel_dec[5] = (m0_adr_i[aw -1 : aw - s215_addr_w ] == s5_addr); assign ssel_dec[6] = (m0_adr_i[aw -1 : aw - s215_addr_w ] == s6_addr); assign ssel_dec[7] = (m0_adr_i[aw -1 : aw - s215_addr_w ] == s7_addr); assign ssel_dec[8] = (m0_adr_i[aw -1 : aw - s215_addr_w ] == s8_addr); assign ssel_dec[9] = (m0_adr_i[aw -1 : aw - s215_addr_w ] == s9_addr); assign ssel_dec[10] = (m0_adr_i[aw -1 : aw - s215_addr_w ] == s10_addr); assign ssel_dec[11] = (m0_adr_i[aw -1 : aw - s215_addr_w ] == s11_addr); assign ssel_dec[12] = (m0_adr_i[aw -1 : aw - s215_addr_w ] == s12_addr); assign ssel_dec[13] = (m0_adr_i[aw -1 : aw - s215_addr_w ] == s13_addr); assign ssel_dec[14] = (m0_adr_i[aw -1 : aw - s215_addr_w ] == s14_addr); assign ssel_dec[15] = (m0_adr_i[aw -1 : aw - s215_addr_w ] == s15_addr); endmodule // wb_1master