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[/] [amber/] [trunk/] [hw/] [vlog/] [system/] [wishbone_arbiter.v] - Rev 35
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////////////////////////////////////////////////////////////////// // // // Wishbone Arbiter // // // // This file is part of the Amber project // // http://www.opencores.org/project,amber // // // // Description // // Arbitrates between two wishbone masters and 13 wishbone // // slave modules. The ethernet MAC wishbone master is given // // priority over the Amber core. // // // // Author(s): // // - Conor Santifort, csantifort.amber@gmail.com // // // ////////////////////////////////////////////////////////////////// // // // Copyright (C) 2010 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 // // // ////////////////////////////////////////////////////////////////// // TODO add module to switch endianess of ethmac i/f module wishbone_arbiter #( parameter WB_DWIDTH = 32, parameter WB_SWIDTH = 4 )( input i_wb_clk, // WISHBONE clock // WISHBONE master 0 - Amber input [31:0] i_m0_wb_adr, input [WB_SWIDTH-1:0] i_m0_wb_sel, input i_m0_wb_we, output [WB_DWIDTH-1:0] o_m0_wb_dat, input [WB_DWIDTH-1:0] i_m0_wb_dat, input i_m0_wb_cyc, input i_m0_wb_stb, output o_m0_wb_ack, output o_m0_wb_err, // WISHBONE master 1 - Ethmac input [31:0] i_m1_wb_adr, input [WB_SWIDTH-1:0] i_m1_wb_sel, input i_m1_wb_we, output [WB_DWIDTH-1:0] o_m1_wb_dat, input [WB_DWIDTH-1:0] i_m1_wb_dat, input i_m1_wb_cyc, input i_m1_wb_stb, output o_m1_wb_ack, output o_m1_wb_err, // WISHBONE slave 0 - Ethmac output [31:0] o_s0_wb_adr, output [WB_SWIDTH-1:0] o_s0_wb_sel, output o_s0_wb_we, input [WB_DWIDTH-1:0] i_s0_wb_dat, output [WB_DWIDTH-1:0] o_s0_wb_dat, output o_s0_wb_cyc, output o_s0_wb_stb, input i_s0_wb_ack, input i_s0_wb_err, // WISHBONE slave 1 - Boot Memory output [31:0] o_s1_wb_adr, output [WB_SWIDTH-1:0] o_s1_wb_sel, output o_s1_wb_we, input [WB_DWIDTH-1:0] i_s1_wb_dat, output [WB_DWIDTH-1:0] o_s1_wb_dat, output o_s1_wb_cyc, output o_s1_wb_stb, input i_s1_wb_ack, input i_s1_wb_err, // WISHBONE slave 2 - Main Memory output [31:0] o_s2_wb_adr, output [WB_SWIDTH-1:0] o_s2_wb_sel, output o_s2_wb_we, input [WB_DWIDTH-1:0] i_s2_wb_dat, output [WB_DWIDTH-1:0] o_s2_wb_dat, output o_s2_wb_cyc, output o_s2_wb_stb, input i_s2_wb_ack, input i_s2_wb_err, // WISHBONE slave 3 - UART 0 output [31:0] o_s3_wb_adr, output [WB_SWIDTH-1:0] o_s3_wb_sel, output o_s3_wb_we, input [WB_DWIDTH-1:0] i_s3_wb_dat, output [WB_DWIDTH-1:0] o_s3_wb_dat, output o_s3_wb_cyc, output o_s3_wb_stb, input i_s3_wb_ack, input i_s3_wb_err, // WISHBONE slave 4 - UART 1 output [31:0] o_s4_wb_adr, output [WB_SWIDTH-1:0] o_s4_wb_sel, output o_s4_wb_we, input [WB_DWIDTH-1:0] i_s4_wb_dat, output [WB_DWIDTH-1:0] o_s4_wb_dat, output o_s4_wb_cyc, output o_s4_wb_stb, input i_s4_wb_ack, input i_s4_wb_err, // WISHBONE slave 5 - Test Module output [31:0] o_s5_wb_adr, output [WB_SWIDTH-1:0] o_s5_wb_sel, output o_s5_wb_we, input [WB_DWIDTH-1:0] i_s5_wb_dat, output [WB_DWIDTH-1:0] o_s5_wb_dat, output o_s5_wb_cyc, output o_s5_wb_stb, input i_s5_wb_ack, input i_s5_wb_err, // WISHBONE slave 6 - Timer Module output [31:0] o_s6_wb_adr, output [WB_SWIDTH-1:0] o_s6_wb_sel, output o_s6_wb_we, input [WB_DWIDTH-1:0] i_s6_wb_dat, output [WB_DWIDTH-1:0] o_s6_wb_dat, output o_s6_wb_cyc, output o_s6_wb_stb, input i_s6_wb_ack, input i_s6_wb_err, // WISHBONE slave 7 - Interrupt Controller output [31:0] o_s7_wb_adr, output [WB_SWIDTH-1:0] o_s7_wb_sel, output o_s7_wb_we, input [WB_DWIDTH-1:0] i_s7_wb_dat, output [WB_DWIDTH-1:0] o_s7_wb_dat, output o_s7_wb_cyc, output o_s7_wb_stb, input i_s7_wb_ack, input i_s7_wb_err ); `include "memory_configuration.v" reg m0_wb_hold_r = 'd0; reg m1_wb_hold_r = 'd0; // wire m0_in_cycle; // wire m1_in_cycle; wire current_master; reg current_master_r = 'd0; wire next_master; wire select_master; wire [3:0] current_slave; wire [31:0] master_adr; wire [WB_SWIDTH-1:0] master_sel; wire master_we; wire [WB_DWIDTH-1:0] master_wdat; wire master_cyc; wire master_stb; wire [WB_DWIDTH-1:0] master_rdat; wire master_ack; wire master_err; // Arbitrate between m0 and m1. Ethmac (m0) always gets priority assign next_master = i_m0_wb_cyc ? 1'd0 : 1'd1; // Use cyc signal for arbitration so block accesses are not split up // assign m0_in_cycle = m0_wb_hold_r && !master_ack; // assign m1_in_cycle = m1_wb_hold_r && !master_ack; // only select a new bus master when the current bus master // daccess ends assign select_master = current_master_r ? !m1_wb_hold_r : !m0_wb_hold_r; assign current_master = select_master ? next_master : current_master_r; always @( posedge i_wb_clk ) begin current_master_r <= current_master; m0_wb_hold_r <= i_m0_wb_stb && !o_m0_wb_ack; m1_wb_hold_r <= i_m1_wb_stb && !o_m1_wb_ack; end // Arbitrate between slaves assign current_slave = in_ethmac ( master_adr ) ? 4'd0 : // Ethmac in_boot_mem ( master_adr ) ? 4'd1 : // Boot memory in_main_mem ( master_adr ) ? 4'd2 : // Main memory in_uart0 ( master_adr ) ? 4'd3 : // UART 0 in_uart1 ( master_adr ) ? 4'd4 : // UART 1 in_test ( master_adr ) ? 4'd5 : // Test Module in_tm ( master_adr ) ? 4'd6 : // Timer Module in_ic ( master_adr ) ? 4'd7 : // Interrupt Controller 4'd2 ; // default to main memory assign master_adr = current_master ? i_m1_wb_adr : i_m0_wb_adr ; assign master_sel = current_master ? i_m1_wb_sel : i_m0_wb_sel ; assign master_wdat = current_master ? i_m1_wb_dat : i_m0_wb_dat ; assign master_we = current_master ? i_m1_wb_we : i_m0_wb_we ; assign master_cyc = current_master ? i_m1_wb_cyc : i_m0_wb_cyc ; assign master_stb = current_master ? i_m1_wb_stb : i_m0_wb_stb ; // Ethmac Slave outputs assign o_s0_wb_adr = master_adr; assign o_s0_wb_dat = master_wdat; assign o_s0_wb_sel = master_sel; assign o_s0_wb_we = current_slave == 4'd0 ? master_we : 1'd0; assign o_s0_wb_cyc = current_slave == 4'd0 ? master_cyc : 1'd0; assign o_s0_wb_stb = current_slave == 4'd0 ? master_stb : 1'd0; // Boot Memory outputs assign o_s1_wb_adr = master_adr; assign o_s1_wb_dat = master_wdat; assign o_s1_wb_sel = master_sel; assign o_s1_wb_we = current_slave == 4'd1 ? master_we : 1'd0; assign o_s1_wb_cyc = current_slave == 4'd1 ? master_cyc : 1'd0; assign o_s1_wb_stb = current_slave == 4'd1 ? master_stb : 1'd0; // Main Memory Outputs assign o_s2_wb_adr = master_adr; assign o_s2_wb_dat = master_wdat; assign o_s2_wb_sel = master_sel; assign o_s2_wb_we = current_slave == 4'd2 ? master_we : 1'd0; assign o_s2_wb_cyc = current_slave == 4'd2 ? master_cyc : 1'd0; assign o_s2_wb_stb = current_slave == 4'd2 ? master_stb : 1'd0; // UART0 Outputs assign o_s3_wb_adr = master_adr; assign o_s3_wb_dat = master_wdat; assign o_s3_wb_sel = master_sel; assign o_s3_wb_we = current_slave == 4'd3 ? master_we : 1'd0; assign o_s3_wb_cyc = current_slave == 4'd3 ? master_cyc : 1'd0; assign o_s3_wb_stb = current_slave == 4'd3 ? master_stb : 1'd0; // UART1 Outputs assign o_s4_wb_adr = master_adr; assign o_s4_wb_dat = master_wdat; assign o_s4_wb_sel = master_sel; assign o_s4_wb_we = current_slave == 4'd4 ? master_we : 1'd0; assign o_s4_wb_cyc = current_slave == 4'd4 ? master_cyc : 1'd0; assign o_s4_wb_stb = current_slave == 4'd4 ? master_stb : 1'd0; // Test Module Outputs assign o_s5_wb_adr = master_adr; assign o_s5_wb_dat = master_wdat; assign o_s5_wb_sel = master_sel; assign o_s5_wb_we = current_slave == 5'd5 ? master_we : 1'd0; assign o_s5_wb_cyc = current_slave == 5'd5 ? master_cyc : 1'd0; assign o_s5_wb_stb = current_slave == 5'd5 ? master_stb : 1'd0; // Timers Outputs assign o_s6_wb_adr = master_adr; assign o_s6_wb_dat = master_wdat; assign o_s6_wb_sel = master_sel; assign o_s6_wb_we = current_slave == 6'd6 ? master_we : 1'd0; assign o_s6_wb_cyc = current_slave == 6'd6 ? master_cyc : 1'd0; assign o_s6_wb_stb = current_slave == 6'd6 ? master_stb : 1'd0; // Interrupt Controller assign o_s7_wb_adr = master_adr; assign o_s7_wb_dat = master_wdat; assign o_s7_wb_sel = master_sel; assign o_s7_wb_we = current_slave == 4'd7 ? master_we : 1'd0; assign o_s7_wb_cyc = current_slave == 4'd7 ? master_cyc : 1'd0; assign o_s7_wb_stb = current_slave == 4'd7 ? master_stb : 1'd0; // Master Outputs assign master_rdat = current_slave == 4'd0 ? i_s0_wb_dat : current_slave == 4'd1 ? i_s1_wb_dat : current_slave == 4'd2 ? i_s2_wb_dat : current_slave == 4'd3 ? i_s3_wb_dat : current_slave == 4'd4 ? i_s4_wb_dat : current_slave == 4'd5 ? i_s5_wb_dat : current_slave == 4'd6 ? i_s6_wb_dat : current_slave == 4'd7 ? i_s7_wb_dat : i_s2_wb_dat ; assign master_ack = current_slave == 4'd0 ? i_s0_wb_ack : current_slave == 4'd1 ? i_s1_wb_ack : current_slave == 4'd2 ? i_s2_wb_ack : current_slave == 4'd3 ? i_s3_wb_ack : current_slave == 4'd4 ? i_s4_wb_ack : current_slave == 4'd5 ? i_s5_wb_ack : current_slave == 4'd6 ? i_s6_wb_ack : current_slave == 4'd7 ? i_s7_wb_ack : i_s2_wb_ack ; assign master_err = current_slave == 4'd0 ? i_s0_wb_err : current_slave == 4'd1 ? i_s1_wb_err : current_slave == 4'd2 ? i_s2_wb_err : current_slave == 4'd3 ? i_s3_wb_err : current_slave == 4'd4 ? i_s4_wb_err : current_slave == 4'd5 ? i_s5_wb_err : current_slave == 4'd6 ? i_s6_wb_err : current_slave == 4'd7 ? i_s7_wb_err : i_s2_wb_err ; // Ethmac Master Outputs assign o_m0_wb_dat = master_rdat; assign o_m0_wb_ack = current_master ? 1'd0 : master_ack ; assign o_m0_wb_err = current_master ? 1'd0 : master_err ; // Amber Master Outputs assign o_m1_wb_dat = master_rdat; assign o_m1_wb_ack = current_master ? master_ack : 1'd0 ; assign o_m1_wb_err = current_master ? master_err : 1'd0 ; endmodule
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