openlane/user_proj/src/soc.v - third_party/shuttle/sky130/mpw-005/slot-025 - Git at Google

 `default_nettype none

 `ifndef CLOCK_HZ
 `define CLOCK_HZ 100_000_000
 `endif

 module soc(
 `ifdef USE_POWER_PINS
   inout vccd1,	// User area 1 1.8V supply
   inout vssd1,	// User area 1 digital ground
 `endif
   input clk,
   input rst,

   input wb_clk,
   input wb_rst,

   output [7:0] LEDS,
   input MCU_UART_TX,
   output MCU_UART_RX,

   input jtag_trst,
   input jtag_tms,
   input jtag_tdi,
   output jtag_tdo,
   input jtag_tck,

   output mprj_ack_o,
 	output [31:0] mprj_dat_o,
 	input [31:0] mprj_dat_i,
   input mprj_cyc_i,
 	input mprj_stb_i,
 	input mprj_we_i,
 	input [3:0] mprj_sel_i,
 	input [31:0] mprj_adr_i,

   output [3:0] o_wmask0,
   output [8:0] o_waddr0,
   output [31:0] o_din0,
   input [31:0] i_dout0,
   output o_web0,
   output o_csb0,

   output [3:0] o_wmask0_1,
   output [8:0] o_waddr0_1,
   output [31:0] o_din0_1,
   input [31:0] i_dout0_1,
   output o_web0_1,
   output o_csb0_1
 );

 `include "wb_interconnect.vh"
 parameter ROM_BASE_ADDRESS =    32'h3000_0000;
 parameter RAM_BASE_ADDRESS =    32'h3000_1000;
 parameter HYPER_BASE_ADDRESS =  32'h3010_0000;
 parameter TIMER_BASE_ADDRESS =  32'h30ff_ff00;
 parameter UART_BASE_ADR =       32'h30ff_fe00;
 parameter LED_BASE_ADR =        32'h30ff_fd00;

 assign wb_m2s_mgmt_adr = mprj_adr_i;
 assign wb_m2s_mgmt_dat = mprj_dat_i;
 assign wb_m2s_mgmt_sel = mprj_sel_i;
 assign wb_m2s_mgmt_we = mprj_we_i;
 assign wb_m2s_mgmt_cyc = mprj_cyc_i;
 assign wb_m2s_mgmt_stb = mprj_stb_i;
 assign mprj_dat_o = wb_s2m_mgmt_dat;
 assign mprj_ack_o = wb_s2m_mgmt_ack;

 `ifdef USE_MEMRAM
 wb_ram cpu0_ram (
 `ifdef USE_POWER_PINS
   .vccd1(vccd1),	// User area 1 1.8V power
   .vssd1(vssd1),	// User area 1 digital ground
 `endif
   .i_clk(wb_clk),
   .i_reset(wb_rst),
   .i_wb_adr(wb_m2s_cpu0_ram_adr),
   .i_wb_dat(wb_m2s_cpu0_ram_dat),
   .i_wb_sel(wb_m2s_cpu0_ram_sel),
   .i_wb_we (wb_m2s_cpu0_ram_we),
   .i_wb_cyc(wb_m2s_cpu0_ram_cyc),
   .i_wb_stb(wb_m2s_cpu0_ram_stb),
   .o_wb_dat(wb_s2m_cpu0_ram_dat),
   .o_wb_ack(wb_s2m_cpu0_ram_ack)
 );
 wb_ram #(
 `ifdef CODE_IN_ROM
   .INITIAL_HEX("firmware/ice40_soc_fw.hex")
 `endif
 ) cpu0_rom (
 `ifdef USE_POWER_PINS
   .vccd1(vccd1),	// User area 1 1.8V power
   .vssd1(vssd1),	// User area 1 digital ground
 `endif
   .i_clk(wb_clk),
   .i_reset(wb_rst),
   .i_wb_adr(wb_m2s_cpu0_rom_adr),
   .i_wb_dat(wb_m2s_cpu0_rom_dat),
   .i_wb_sel(wb_m2s_cpu0_rom_sel),
   .i_wb_we (wb_m2s_cpu0_rom_we),
   .i_wb_cyc(wb_m2s_cpu0_rom_cyc),
   .i_wb_stb(wb_m2s_cpu0_rom_stb),
   .o_wb_dat(wb_s2m_cpu0_rom_dat),
   .o_wb_ack(wb_s2m_cpu0_rom_ack)
 );
 `else //USE_MEMRAM
 wb_openram_wrapper #(
   .BASE_ADDR(RAM_BASE_ADDRESS),
   .ADDR_WIDTH(9) //log2(512)
 ) wb_openram0 (
 `ifdef USE_POWER_PINS
   .vccd1(vccd1),	// User area 1 1.8V power
   .vssd1(vssd1),	// User area 1 digital ground
 `endif
   .wb_clk_i(wb_clk),
   .wb_rst_i(wb_rst),
   .wbs_adr_i(wb_m2s_cpu0_ram_adr),
   .wbs_dat_i(wb_m2s_cpu0_ram_dat),
   .wbs_sel_i(wb_m2s_cpu0_ram_sel),
   .wbs_we_i(wb_m2s_cpu0_ram_we),
   .wbs_cyc_i(wb_m2s_cpu0_ram_cyc),
   .wbs_stb_i(wb_m2s_cpu0_ram_stb),
   .wbs_dat_o(wb_s2m_cpu0_ram_dat),
   .wbs_ack_o(wb_s2m_cpu0_ram_ack),
   .ram_csb0(o_csb0),
   .ram_web0(o_web0),
   .ram_wmask0(o_wmask0),
   .ram_addr0(o_waddr0),
   .ram_din0(o_din0),
   .ram_dout0(i_dout0)
 );
 wb_openram_wrapper #(
   .BASE_ADDR(ROM_BASE_ADDRESS),
   .ADDR_WIDTH(9) //log2(512)
 ) wb_openram1 (
 `ifdef USE_POWER_PINS
   .vccd1(vccd1),	// User area 1 1.8V power
   .vssd1(vssd1),	// User area 1 digital ground
 `endif
   .wb_clk_i(wb_clk),
   .wb_rst_i(wb_rst),
   .wbs_adr_i(wb_m2s_cpu0_rom_adr),
   .wbs_dat_i(wb_m2s_cpu0_rom_dat),
   .wbs_sel_i(wb_m2s_cpu0_rom_sel),
   .wbs_we_i(wb_m2s_cpu0_rom_we),
   .wbs_cyc_i(wb_m2s_cpu0_rom_cyc),
   .wbs_stb_i(wb_m2s_cpu0_rom_stb),
   .wbs_dat_o(wb_s2m_cpu0_rom_dat),
   .wbs_ack_o(wb_s2m_cpu0_rom_ack),
   .ram_csb0(o_csb0_1),
   .ram_web0(o_web0_1),
   .ram_wmask0(o_wmask0_1),
   .ram_addr0(o_waddr0_1),
   .ram_din0(o_din0_1),
   .ram_dout0(i_dout0_1)
 );
 `endif //USE_MEMRAM

 // Timer for generating the timer interrupt
 wire timer_interrupt;
 timer_wb #(
   .DEFAULT_PRESCALER(`CLOCK_HZ / 1000 - 1)
 ) timer0 (
 `ifdef USE_POWER_PINS
   .vccd1(vccd1),	// User area 1 1.8V power
   .vssd1(vssd1),	// User area 1 digital ground
 `endif
   .i_clk(wb_clk),
   .i_reset(wb_rst),
   .o_timer_trigger(timer_interrupt),
   .i_wb_adr(wb_m2s_timer0_adr),
   .i_wb_dat(wb_m2s_timer0_dat),
   .i_wb_sel(wb_m2s_timer0_sel),
   .i_wb_we (wb_m2s_timer0_we),
   .i_wb_cyc(wb_m2s_timer0_cyc),
   .i_wb_stb(wb_m2s_timer0_stb),
   .o_wb_dat(wb_s2m_timer0_dat),
   .o_wb_ack(wb_s2m_timer0_ack)
 );

 // Uart for console logging
 `ifndef USE_OBSOLETE_UART
 simpleuartA_wb #(
   .BASE_ADR(UART_BASE_ADR)
 ) simpleuartA0 (
   .wb_clk_i(wb_clk),
   .wb_rst_i(wb_rst),
   .wb_adr_i(wb_m2s_uart0_adr),
   .wb_dat_i(wb_m2s_uart0_dat),
   .wb_sel_i(wb_m2s_uart0_sel),
   .wb_we_i(wb_m2s_uart0_we),
   .wb_cyc_i(wb_m2s_uart0_cyc),
   .wb_stb_i(wb_m2s_uart0_stb),
   .wb_ack_o(wb_s2m_uart0_ack),
   .wb_dat_o(wb_s2m_uart0_dat),

   .ser_tx(MCU_UART_RX),
   .ser_rx(MCU_UART_TX)
 );
 `else
 uart_wb #(
   .TX_BUFSIZE(32),
   .RX_BUFSIZE(32),
   .DATA_WIDTH(8)
 ) uart0 (
 `ifdef USE_POWER_PINS
   .vccd1(vccd1),	// User area 1 1.8V power
   .vssd1(vssd1),	// User area 1 digital ground
 `endif
   .i_clk(wb_clk),
   .i_reset(wb_rst),
   .i_uart_rx(MCU_UART_TX),
   .o_uart_tx(MCU_UART_RX),
   .i_wb_adr(wb_m2s_uart0_adr),
   .i_wb_dat(wb_m2s_uart0_dat),
   .i_wb_sel(wb_m2s_uart0_sel),
   .i_wb_we (wb_m2s_uart0_we),
   .i_wb_cyc(wb_m2s_uart0_cyc),
   .i_wb_stb(wb_m2s_uart0_stb),
   .o_wb_dat(wb_s2m_uart0_dat),
   .o_wb_ack(wb_s2m_uart0_ack)
 );
 `endif

 // LEDS
 wb_led led (
 `ifdef USE_POWER_PINS
   .vccd1(vccd1),	// User area 1 1.8V power
   .vssd1(vssd1),	// User area 1 digital ground
 `endif
   .i_clk(wb_clk),
   .i_reset(wb_rst),
   .o_leds(LEDS),
   .i_wb_adr(wb_m2s_led0_adr),
   .i_wb_dat(wb_m2s_led0_dat),
   .i_wb_sel(wb_m2s_led0_sel),
   .i_wb_we (wb_m2s_led0_we),
   .i_wb_cyc(wb_m2s_led0_cyc),
   .i_wb_stb(wb_m2s_led0_stb),
   .o_wb_dat(wb_s2m_led0_dat),
   .o_wb_ack(wb_s2m_led0_ack)
 );

 /*
 # CPU
 cd riscv/SpinalHDL
 sbt clean
 sbt compile
 sbt tasks
 sbt publishLocal
 cd riscv/VexRiscv
 sbt "show discoveredMainClasses"
 sbt "runMain vexriscv.demo.GenVexRiscv"
 sbt "runMain vexriscv.demo.GenRB"
 */

 VexRiscv cpu0 (
 `ifdef USE_POWER_PINS
   .vccd1(vccd1),	// User area 1 1.8V power
   .vssd1(vssd1),	// User area 1 digital ground
 `endif

   .clk(clk),
   .reset(rst),

   .timerInterrupt(timer_interrupt),
   .externalInterrupt(1'b0),
   .softwareInterrupt(1'b0),

   .iBusWishbone_CYC(wb_m2s_cpu0_ibus_cyc),
   .iBusWishbone_STB(wb_m2s_cpu0_ibus_stb),
   .iBusWishbone_ACK(wb_s2m_cpu0_ibus_ack),
   .iBusWishbone_WE(wb_m2s_cpu0_ibus_we),
   .iBusWishbone_ADR(wb_m2s_cpu0_ibus_adr[31:2]), // Low 2 bits are always zero
   .iBusWishbone_DAT_MISO(wb_s2m_cpu0_ibus_dat),
   .iBusWishbone_DAT_MOSI(wb_m2s_cpu0_ibus_dat),
   .iBusWishbone_SEL(wb_m2s_cpu0_ibus_sel),
   .iBusWishbone_ERR(wb_s2m_cpu0_ibus_err),
   .iBusWishbone_BTE(wb_m2s_cpu0_ibus_bte),
   .iBusWishbone_CTI(wb_m2s_cpu0_ibus_cti),

   .dBusWishbone_CYC(wb_m2s_cpu0_dbus_cyc),
   .dBusWishbone_STB(wb_m2s_cpu0_dbus_stb),
   .dBusWishbone_ACK(wb_s2m_cpu0_dbus_ack),
   .dBusWishbone_WE(wb_m2s_cpu0_dbus_we),
   .dBusWishbone_ADR(wb_m2s_cpu0_dbus_adr[31:2]), // Low 2 bits are always zero
   .dBusWishbone_DAT_MISO(wb_s2m_cpu0_dbus_dat),
   .dBusWishbone_DAT_MOSI(wb_m2s_cpu0_dbus_dat),
   .dBusWishbone_SEL(wb_m2s_cpu0_dbus_sel),
   .dBusWishbone_ERR(wb_s2m_cpu0_dbus_err),
   .dBusWishbone_BTE(wb_m2s_cpu0_dbus_bte),
   .dBusWishbone_CTI(wb_m2s_cpu0_dbus_cti),

   .jtag_rst(jtag_trst),
   .jtag_tms(jtag_tms),
   .jtag_tdi(jtag_tdi),
   .jtag_tdo(jtag_tdo),
   .jtag_tck(jtag_tck)
 );

 endmodule
	`default_nettype none

	`ifndef CLOCK_HZ
	`define CLOCK_HZ 100_000_000
	`endif

	module soc(
	`ifdef USE_POWER_PINS
	inout vccd1, // User area 1 1.8V supply
	inout vssd1, // User area 1 digital ground
	`endif
	input clk,
	input rst,

	input wb_clk,
	input wb_rst,

	output [7:0] LEDS,
	input MCU_UART_TX,
	output MCU_UART_RX,

	input jtag_trst,
	input jtag_tms,
	input jtag_tdi,
	output jtag_tdo,
	input jtag_tck,

	output mprj_ack_o,
	output [31:0] mprj_dat_o,
	input [31:0] mprj_dat_i,
	input mprj_cyc_i,
	input mprj_stb_i,
	input mprj_we_i,
	input [3:0] mprj_sel_i,
	input [31:0] mprj_adr_i,

	output [3:0] o_wmask0,
	output [8:0] o_waddr0,
	output [31:0] o_din0,
	input [31:0] i_dout0,
	output o_web0,
	output o_csb0,

	output [3:0] o_wmask0_1,
	output [8:0] o_waddr0_1,
	output [31:0] o_din0_1,
	input [31:0] i_dout0_1,
	output o_web0_1,
	output o_csb0_1
	);

	`include "wb_interconnect.vh"
	parameter ROM_BASE_ADDRESS = 32'h3000_0000;
	parameter RAM_BASE_ADDRESS = 32'h3000_1000;
	parameter HYPER_BASE_ADDRESS = 32'h3010_0000;
	parameter TIMER_BASE_ADDRESS = 32'h30ff_ff00;
	parameter UART_BASE_ADR = 32'h30ff_fe00;
	parameter LED_BASE_ADR = 32'h30ff_fd00;

	assign wb_m2s_mgmt_adr = mprj_adr_i;
	assign wb_m2s_mgmt_dat = mprj_dat_i;
	assign wb_m2s_mgmt_sel = mprj_sel_i;
	assign wb_m2s_mgmt_we = mprj_we_i;
	assign wb_m2s_mgmt_cyc = mprj_cyc_i;
	assign wb_m2s_mgmt_stb = mprj_stb_i;
	assign mprj_dat_o = wb_s2m_mgmt_dat;
	assign mprj_ack_o = wb_s2m_mgmt_ack;

	`ifdef USE_MEMRAM
	wb_ram cpu0_ram (
	`ifdef USE_POWER_PINS
	.vccd1(vccd1), // User area 1 1.8V power
	.vssd1(vssd1), // User area 1 digital ground
	`endif
	.i_clk(wb_clk),
	.i_reset(wb_rst),
	.i_wb_adr(wb_m2s_cpu0_ram_adr),
	.i_wb_dat(wb_m2s_cpu0_ram_dat),
	.i_wb_sel(wb_m2s_cpu0_ram_sel),
	.i_wb_we (wb_m2s_cpu0_ram_we),
	.i_wb_cyc(wb_m2s_cpu0_ram_cyc),
	.i_wb_stb(wb_m2s_cpu0_ram_stb),
	.o_wb_dat(wb_s2m_cpu0_ram_dat),
	.o_wb_ack(wb_s2m_cpu0_ram_ack)
	);
	wb_ram #(
	`ifdef CODE_IN_ROM
	.INITIAL_HEX("firmware/ice40_soc_fw.hex")
	`endif
	) cpu0_rom (
	`ifdef USE_POWER_PINS
	.vccd1(vccd1), // User area 1 1.8V power
	.vssd1(vssd1), // User area 1 digital ground
	`endif
	.i_clk(wb_clk),
	.i_reset(wb_rst),
	.i_wb_adr(wb_m2s_cpu0_rom_adr),
	.i_wb_dat(wb_m2s_cpu0_rom_dat),
	.i_wb_sel(wb_m2s_cpu0_rom_sel),
	.i_wb_we (wb_m2s_cpu0_rom_we),
	.i_wb_cyc(wb_m2s_cpu0_rom_cyc),
	.i_wb_stb(wb_m2s_cpu0_rom_stb),
	.o_wb_dat(wb_s2m_cpu0_rom_dat),
	.o_wb_ack(wb_s2m_cpu0_rom_ack)
	);
	`else //USE_MEMRAM
	wb_openram_wrapper #(
	.BASE_ADDR(RAM_BASE_ADDRESS),
	.ADDR_WIDTH(9) //log2(512)
	) wb_openram0 (
	`ifdef USE_POWER_PINS
	.vccd1(vccd1), // User area 1 1.8V power
	.vssd1(vssd1), // User area 1 digital ground
	`endif
	.wb_clk_i(wb_clk),
	.wb_rst_i(wb_rst),
	.wbs_adr_i(wb_m2s_cpu0_ram_adr),
	.wbs_dat_i(wb_m2s_cpu0_ram_dat),
	.wbs_sel_i(wb_m2s_cpu0_ram_sel),
	.wbs_we_i(wb_m2s_cpu0_ram_we),
	.wbs_cyc_i(wb_m2s_cpu0_ram_cyc),
	.wbs_stb_i(wb_m2s_cpu0_ram_stb),
	.wbs_dat_o(wb_s2m_cpu0_ram_dat),
	.wbs_ack_o(wb_s2m_cpu0_ram_ack),
	.ram_csb0(o_csb0),
	.ram_web0(o_web0),
	.ram_wmask0(o_wmask0),
	.ram_addr0(o_waddr0),
	.ram_din0(o_din0),
	.ram_dout0(i_dout0)
	);
	wb_openram_wrapper #(
	.BASE_ADDR(ROM_BASE_ADDRESS),
	.ADDR_WIDTH(9) //log2(512)
	) wb_openram1 (
	`ifdef USE_POWER_PINS
	.vccd1(vccd1), // User area 1 1.8V power
	.vssd1(vssd1), // User area 1 digital ground
	`endif
	.wb_clk_i(wb_clk),
	.wb_rst_i(wb_rst),
	.wbs_adr_i(wb_m2s_cpu0_rom_adr),
	.wbs_dat_i(wb_m2s_cpu0_rom_dat),
	.wbs_sel_i(wb_m2s_cpu0_rom_sel),
	.wbs_we_i(wb_m2s_cpu0_rom_we),
	.wbs_cyc_i(wb_m2s_cpu0_rom_cyc),
	.wbs_stb_i(wb_m2s_cpu0_rom_stb),
	.wbs_dat_o(wb_s2m_cpu0_rom_dat),
	.wbs_ack_o(wb_s2m_cpu0_rom_ack),
	.ram_csb0(o_csb0_1),
	.ram_web0(o_web0_1),
	.ram_wmask0(o_wmask0_1),
	.ram_addr0(o_waddr0_1),
	.ram_din0(o_din0_1),
	.ram_dout0(i_dout0_1)
	);
	`endif //USE_MEMRAM

	// Timer for generating the timer interrupt
	wire timer_interrupt;
	timer_wb #(
	.DEFAULT_PRESCALER(`CLOCK_HZ / 1000 - 1)
	) timer0 (
	`ifdef USE_POWER_PINS
	.vccd1(vccd1), // User area 1 1.8V power
	.vssd1(vssd1), // User area 1 digital ground
	`endif
	.i_clk(wb_clk),
	.i_reset(wb_rst),
	.o_timer_trigger(timer_interrupt),
	.i_wb_adr(wb_m2s_timer0_adr),
	.i_wb_dat(wb_m2s_timer0_dat),
	.i_wb_sel(wb_m2s_timer0_sel),
	.i_wb_we (wb_m2s_timer0_we),
	.i_wb_cyc(wb_m2s_timer0_cyc),
	.i_wb_stb(wb_m2s_timer0_stb),
	.o_wb_dat(wb_s2m_timer0_dat),
	.o_wb_ack(wb_s2m_timer0_ack)
	);

	// Uart for console logging
	`ifndef USE_OBSOLETE_UART
	simpleuartA_wb #(
	.BASE_ADR(UART_BASE_ADR)
	) simpleuartA0 (
	.wb_clk_i(wb_clk),
	.wb_rst_i(wb_rst),
	.wb_adr_i(wb_m2s_uart0_adr),
	.wb_dat_i(wb_m2s_uart0_dat),
	.wb_sel_i(wb_m2s_uart0_sel),
	.wb_we_i(wb_m2s_uart0_we),
	.wb_cyc_i(wb_m2s_uart0_cyc),
	.wb_stb_i(wb_m2s_uart0_stb),
	.wb_ack_o(wb_s2m_uart0_ack),
	.wb_dat_o(wb_s2m_uart0_dat),

	.ser_tx(MCU_UART_RX),
	.ser_rx(MCU_UART_TX)
	);
	`else
	uart_wb #(
	.TX_BUFSIZE(32),
	.RX_BUFSIZE(32),
	.DATA_WIDTH(8)
	) uart0 (
	`ifdef USE_POWER_PINS
	.vccd1(vccd1), // User area 1 1.8V power
	.vssd1(vssd1), // User area 1 digital ground
	`endif
	.i_clk(wb_clk),
	.i_reset(wb_rst),
	.i_uart_rx(MCU_UART_TX),
	.o_uart_tx(MCU_UART_RX),
	.i_wb_adr(wb_m2s_uart0_adr),
	.i_wb_dat(wb_m2s_uart0_dat),
	.i_wb_sel(wb_m2s_uart0_sel),
	.i_wb_we (wb_m2s_uart0_we),
	.i_wb_cyc(wb_m2s_uart0_cyc),
	.i_wb_stb(wb_m2s_uart0_stb),
	.o_wb_dat(wb_s2m_uart0_dat),
	.o_wb_ack(wb_s2m_uart0_ack)
	);
	`endif

	// LEDS
	wb_led led (
	`ifdef USE_POWER_PINS
	.vccd1(vccd1), // User area 1 1.8V power
	.vssd1(vssd1), // User area 1 digital ground
	`endif
	.i_clk(wb_clk),
	.i_reset(wb_rst),
	.o_leds(LEDS),
	.i_wb_adr(wb_m2s_led0_adr),
	.i_wb_dat(wb_m2s_led0_dat),
	.i_wb_sel(wb_m2s_led0_sel),
	.i_wb_we (wb_m2s_led0_we),
	.i_wb_cyc(wb_m2s_led0_cyc),
	.i_wb_stb(wb_m2s_led0_stb),
	.o_wb_dat(wb_s2m_led0_dat),
	.o_wb_ack(wb_s2m_led0_ack)
	);

	/*
	# CPU
	cd riscv/SpinalHDL
	sbt clean
	sbt compile
	sbt tasks
	sbt publishLocal
	cd riscv/VexRiscv
	sbt "show discoveredMainClasses"
	sbt "runMain vexriscv.demo.GenVexRiscv"
	sbt "runMain vexriscv.demo.GenRB"
	*/

	VexRiscv cpu0 (
	`ifdef USE_POWER_PINS
	.vccd1(vccd1), // User area 1 1.8V power
	.vssd1(vssd1), // User area 1 digital ground
	`endif

	.clk(clk),
	.reset(rst),

	.timerInterrupt(timer_interrupt),
	.externalInterrupt(1'b0),
	.softwareInterrupt(1'b0),

	.iBusWishbone_CYC(wb_m2s_cpu0_ibus_cyc),
	.iBusWishbone_STB(wb_m2s_cpu0_ibus_stb),
	.iBusWishbone_ACK(wb_s2m_cpu0_ibus_ack),
	.iBusWishbone_WE(wb_m2s_cpu0_ibus_we),
	.iBusWishbone_ADR(wb_m2s_cpu0_ibus_adr[31:2]), // Low 2 bits are always zero
	.iBusWishbone_DAT_MISO(wb_s2m_cpu0_ibus_dat),
	.iBusWishbone_DAT_MOSI(wb_m2s_cpu0_ibus_dat),
	.iBusWishbone_SEL(wb_m2s_cpu0_ibus_sel),
	.iBusWishbone_ERR(wb_s2m_cpu0_ibus_err),
	.iBusWishbone_BTE(wb_m2s_cpu0_ibus_bte),
	.iBusWishbone_CTI(wb_m2s_cpu0_ibus_cti),

	.dBusWishbone_CYC(wb_m2s_cpu0_dbus_cyc),
	.dBusWishbone_STB(wb_m2s_cpu0_dbus_stb),
	.dBusWishbone_ACK(wb_s2m_cpu0_dbus_ack),
	.dBusWishbone_WE(wb_m2s_cpu0_dbus_we),
	.dBusWishbone_ADR(wb_m2s_cpu0_dbus_adr[31:2]), // Low 2 bits are always zero
	.dBusWishbone_DAT_MISO(wb_s2m_cpu0_dbus_dat),
	.dBusWishbone_DAT_MOSI(wb_m2s_cpu0_dbus_dat),
	.dBusWishbone_SEL(wb_m2s_cpu0_dbus_sel),
	.dBusWishbone_ERR(wb_s2m_cpu0_dbus_err),
	.dBusWishbone_BTE(wb_m2s_cpu0_dbus_bte),
	.dBusWishbone_CTI(wb_m2s_cpu0_dbus_cti),

	.jtag_rst(jtag_trst),
	.jtag_tms(jtag_tms),
	.jtag_tdi(jtag_tdi),
	.jtag_tdo(jtag_tdo),
	.jtag_tck(jtag_tck)
	);

	endmodule