corundum/example/KC705/fpga_rgmii/rtl/fpga.v

/*

Copyright (c) 2014-2018 Alex Forencich

Permission is hereby granted, free of charge, to any person obtaining a copy
of this software and associated documentation files (the "Software"), to deal
in the Software without restriction, including without limitation the rights
to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
copies of the Software, and to permit persons to whom the Software is
furnished to do so, subject to the following conditions:

The above copyright notice and this permission notice shall be included in
all copies or substantial portions of the Software.

THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
THE SOFTWARE.

*/

// Language: Verilog 2001

`resetall
`timescale 1ns / 1ps
`default_nettype none

/*
 * FPGA top-level module
 */
module fpga (
    /*
     * Clock: 200MHz
     * Reset: Push button, active high
     */
    input  wire       clk_200mhz_p,
    input  wire       clk_200mhz_n,
    input  wire       reset,

    /*
     * GPIO
     */
    input  wire       btnu,
    input  wire       btnl,
    input  wire       btnd,
    input  wire       btnr,
    input  wire       btnc,
    input  wire [3:0] sw,
    output wire [7:0] led,

    /*
     * Ethernet: 1000BASE-T RGMII
     */
    input  wire       phy_rx_clk,
    input  wire [3:0] phy_rxd,
    input  wire       phy_rx_ctl,
    output wire       phy_tx_clk,
    output wire [3:0] phy_txd,
    output wire       phy_tx_ctl,
    output wire       phy_reset_n,
    input  wire       phy_int_n,

    /*
     * UART: 500000 bps, 8N1
     */
    input  wire       uart_rxd,
    output wire       uart_txd,
    output wire       uart_rts,
    input  wire       uart_cts
);

// Clock and reset

wire clk_200mhz_ibufg;

// Internal 125 MHz clock
wire clk_mmcm_out;
wire clk_int;
wire clk90_mmcm_out;
wire clk90_int;
wire rst_int;

wire clk_200mhz_mmcm_out;
wire clk_200mhz_int;

wire mmcm_rst = reset;
wire mmcm_locked;
wire mmcm_clkfb;

IBUFGDS
clk_200mhz_ibufgds_inst(
    .I(clk_200mhz_p),
    .IB(clk_200mhz_n),
    .O(clk_200mhz_ibufg)
);

// MMCM instance
// 200 MHz in, 125 MHz out
// PFD range: 10 MHz to 500 MHz
// VCO range: 600 MHz to 1440 MHz
// M = 5, D = 1 sets Fvco = 1000 MHz (in range)
// Divide by 8 to get output frequency of 125 MHz
// Need two 125 MHz outputs with 90 degree offset
// Also need 200 MHz out for IODELAY
// 1000 / 5 = 200 MHz
MMCME2_BASE #(
    .BANDWIDTH("OPTIMIZED"),
    .CLKOUT0_DIVIDE_F(8),
    .CLKOUT0_DUTY_CYCLE(0.5),
    .CLKOUT0_PHASE(0),
    .CLKOUT1_DIVIDE(8),
    .CLKOUT1_DUTY_CYCLE(0.5),
    .CLKOUT1_PHASE(90),
    .CLKOUT2_DIVIDE(5),
    .CLKOUT2_DUTY_CYCLE(0.5),
    .CLKOUT2_PHASE(0),
    .CLKOUT3_DIVIDE(1),
    .CLKOUT3_DUTY_CYCLE(0.5),
    .CLKOUT3_PHASE(0),
    .CLKOUT4_DIVIDE(1),
    .CLKOUT4_DUTY_CYCLE(0.5),
    .CLKOUT4_PHASE(0),
    .CLKOUT5_DIVIDE(1),
    .CLKOUT5_DUTY_CYCLE(0.5),
    .CLKOUT5_PHASE(0),
    .CLKOUT6_DIVIDE(1),
    .CLKOUT6_DUTY_CYCLE(0.5),
    .CLKOUT6_PHASE(0),
    .CLKFBOUT_MULT_F(5),
    .CLKFBOUT_PHASE(0),
    .DIVCLK_DIVIDE(1),
    .REF_JITTER1(0.010),
    .CLKIN1_PERIOD(5.0),
    .STARTUP_WAIT("FALSE"),
    .CLKOUT4_CASCADE("FALSE")
)
clk_mmcm_inst (
    .CLKIN1(clk_200mhz_ibufg),
    .CLKFBIN(mmcm_clkfb),
    .RST(mmcm_rst),
    .PWRDWN(1'b0),
    .CLKOUT0(clk_mmcm_out),
    .CLKOUT0B(),
    .CLKOUT1(clk90_mmcm_out),
    .CLKOUT1B(),
    .CLKOUT2(clk_200mhz_mmcm_out),
    .CLKOUT2B(),
    .CLKOUT3(),
    .CLKOUT3B(),
    .CLKOUT4(),
    .CLKOUT5(),
    .CLKOUT6(),
    .CLKFBOUT(mmcm_clkfb),
    .CLKFBOUTB(),
    .LOCKED(mmcm_locked)
);

BUFG
clk_bufg_inst (
    .I(clk_mmcm_out),
    .O(clk_int)
);

BUFG
clk90_bufg_inst (
    .I(clk90_mmcm_out),
    .O(clk90_int)
);

BUFG
clk_200mhz_bufg_inst (
    .I(clk_200mhz_mmcm_out),
    .O(clk_200mhz_int)
);

sync_reset #(
    .N(4)
)
sync_reset_inst (
    .clk(clk_int),
    .rst(~mmcm_locked),
    .out(rst_int)
);

// GPIO
wire btnu_int;
wire btnl_int;
wire btnd_int;
wire btnr_int;
wire btnc_int;
wire [3:0] sw_int;

debounce_switch #(
    .WIDTH(9),
    .N(4),
    .RATE(125000)
)
debounce_switch_inst (
    .clk(clk_int),
    .rst(rst_int),
    .in({btnu,
        btnl,
        btnd,
        btnr,
        btnc,
        sw}),
    .out({btnu_int,
        btnl_int,
        btnd_int,
        btnr_int,
        btnc_int,
        sw_int})
);

wire uart_rxd_int;
wire uart_cts_int;

sync_signal #(
    .WIDTH(2),
    .N(2)
)
sync_signal_inst (
    .clk(clk_int),
    .in({uart_rxd, uart_cts}),
    .out({uart_rxd_int, uart_cts_int})
);

// IODELAY elements for RGMII interface to PHY
wire [3:0] phy_rxd_delay;
wire       phy_rx_ctl_delay;

IDELAYCTRL
idelayctrl_inst (
    .REFCLK(clk_200mhz_int),
    .RST(rst_int),
    .RDY()
);

IDELAYE2 #(
    .IDELAY_TYPE("FIXED")
)
phy_rxd_idelay_0 (
    .IDATAIN(phy_rxd[0]),
    .DATAOUT(phy_rxd_delay[0]),
    .DATAIN(1'b0),
    .C(1'b0),
    .CE(1'b0),
    .INC(1'b0),
    .CINVCTRL(1'b0),
    .CNTVALUEIN(5'd0),
    .CNTVALUEOUT(),
    .LD(1'b0),
    .LDPIPEEN(1'b0),
    .REGRST(1'b0)
);

IDELAYE2 #(
    .IDELAY_TYPE("FIXED")
)
phy_rxd_idelay_1 (
    .IDATAIN(phy_rxd[1]),
    .DATAOUT(phy_rxd_delay[1]),
    .DATAIN(1'b0),
    .C(1'b0),
    .CE(1'b0),
    .INC(1'b0),
    .CINVCTRL(1'b0),
    .CNTVALUEIN(5'd0),
    .CNTVALUEOUT(),
    .LD(1'b0),
    .LDPIPEEN(1'b0),
    .REGRST(1'b0)
);

IDELAYE2 #(
    .IDELAY_TYPE("FIXED")
)
phy_rxd_idelay_2 (
    .IDATAIN(phy_rxd[2]),
    .DATAOUT(phy_rxd_delay[2]),
    .DATAIN(1'b0),
    .C(1'b0),
    .CE(1'b0),
    .INC(1'b0),
    .CINVCTRL(1'b0),
    .CNTVALUEIN(5'd0),
    .CNTVALUEOUT(),
    .LD(1'b0),
    .LDPIPEEN(1'b0),
    .REGRST(1'b0)
);

IDELAYE2 #(
    .IDELAY_TYPE("FIXED")
)
phy_rxd_idelay_3 (
    .IDATAIN(phy_rxd[3]),
    .DATAOUT(phy_rxd_delay[3]),
    .DATAIN(1'b0),
    .C(1'b0),
    .CE(1'b0),
    .INC(1'b0),
    .CINVCTRL(1'b0),
    .CNTVALUEIN(5'd0),
    .CNTVALUEOUT(),
    .LD(1'b0),
    .LDPIPEEN(1'b0),
    .REGRST(1'b0)
);

IDELAYE2 #(
    .IDELAY_TYPE("FIXED")
)
phy_rx_ctl_idelay (
    .IDATAIN(phy_rx_ctl),
    .DATAOUT(phy_rx_ctl_delay),
    .DATAIN(1'b0),
    .C(1'b0),
    .CE(1'b0),
    .INC(1'b0),
    .CINVCTRL(1'b0),
    .CNTVALUEIN(5'd0),
    .CNTVALUEOUT(),
    .LD(1'b0),
    .LDPIPEEN(1'b0),
    .REGRST(1'b0)
);

fpga_core #(
    .TARGET("XILINX")
)
core_inst (
    /*
     * Clock: 125MHz
     * Synchronous reset
     */
    .clk(clk_int),
    .clk90(clk90_int),
    .rst(rst_int),
    /*
     * GPIO
     */
    .btnu(btnu_int),
    .btnl(btnl_int),
    .btnd(btnd_int),
    .btnr(btnr_int),
    .btnc(btnc_int),
    .sw(sw_int),
    .led(led),
    /*
     * Ethernet: 1000BASE-T RGMII
     */
    .phy_rx_clk(phy_rx_clk),
    .phy_rxd(phy_rxd_delay),
    .phy_rx_ctl(phy_rx_ctl_delay),
    .phy_tx_clk(phy_tx_clk),
    .phy_txd(phy_txd),
    .phy_tx_ctl(phy_tx_ctl),
    .phy_reset_n(phy_reset_n),
    .phy_int_n(phy_int_n),
    /*
     * UART: 115200 bps, 8N1
     */
    .uart_rxd(uart_rxd_int),
    .uart_txd(uart_txd),
    .uart_rts(uart_rts),
    .uart_cts(uart_cts_int)
);

endmodule

`resetall