Add KC705 GMII example design

2025-01-28 07:03:08 +08:00 · 2019-05-02 19:29:47 -07:00 · 2019-05-02 19:29:47 -07:00 · 1d61626785
commit 1d61626785
parent 696c634726
20 changed files with 1814 additions and 0 deletions
--- a/example/KC705/fpga_gmii/Makefile
+++ b/example/KC705/fpga_gmii/Makefile
@ -0,0 +1,25 @@
 # Targets
 TARGETS:=
 # Subdirectories
 SUBDIRS = fpga
 SUBDIRS_CLEAN = $(patsubst %,%.clean,$(SUBDIRS))
 # Rules
 .PHONY: all
 all: $(SUBDIRS) $(TARGETS)
 .PHONY: $(SUBDIRS)
 $(SUBDIRS):
 	cd $@ && $(MAKE)
 .PHONY: $(SUBDIRS_CLEAN)
 $(SUBDIRS_CLEAN):
 	cd $(@:.clean=) && $(MAKE) clean
 .PHONY: clean
 clean: $(SUBDIRS_CLEAN)
 	-rm -rf $(TARGETS)
 program:
 	#djtgcfg prog -d Atlys --index 0 --file fpga/fpga.bit
--- a/example/KC705/fpga_gmii/README.md
+++ b/example/KC705/fpga_gmii/README.md
@ -0,0 +1,28 @@
 # Verilog Ethernet KC705 Example Design
 ## Introduction
 This example design targets the Xilinx KC705 FPGA board.
 The design by default listens to UDP port 1234 at IP address 192.168.1.128 and
 will echo back any packets received.  The design will also respond correctly
 to ARP requests.  
 Configure the PHY for GMII by placing J29 and J30 across pins 1 and 2 and
 opening J64.
 FPGA: XC7K325T-2FFG900C
 PHY: Marvell 88E1111
 ## How to build
 Run make to build.  Ensure that the Xilinx Vivado toolchain components are
 in PATH.  
 ## How to test
 Run make program to program the KC705 board with Vivado.  Then run netcat -u
 192.168.1.128 1234 to open a UDP connection to port 1234.  Any text entered
 into netcat will be echoed back after pressing enter.  
--- a/example/KC705/fpga_gmii/clock.xdc
+++ b/example/KC705/fpga_gmii/clock.xdc
@ -0,0 +1,4 @@
 # Clock constraints
 # BUFGMUX outputs
 set_clock_groups -physically_exclusive -group clk_mmcm_out -group phy_tx_clk
--- a/example/KC705/fpga_gmii/common/vivado.mk
+++ b/example/KC705/fpga_gmii/common/vivado.mk
@ -0,0 +1,118 @@
 ###################################################################
 # 
 # Xilinx Vivado FPGA Makefile
 # 
 # Copyright (c) 2016 Alex Forencich
 # 
 ###################################################################
 # 
 # Parameters:
 # FPGA_TOP - Top module name
 # FPGA_FAMILY - FPGA family (e.g. VirtexUltrascale)
 # FPGA_DEVICE - FPGA device (e.g. xcvu095-ffva2104-2-e)
 # SYN_FILES - space-separated list of source files
 # INC_FILES - space-separated list of include files
 # XDC_FILES - space-separated list of timing constraint files
 # XCI_FILES - space-separated list of IP XCI files
 # 
 # Example:
 # 
 # FPGA_TOP = fpga
 # FPGA_FAMILY = VirtexUltrascale
 # FPGA_DEVICE = xcvu095-ffva2104-2-e
 # SYN_FILES = rtl/fpga.v
 # XDC_FILES = fpga.xdc
 # XCI_FILES = ip/pcspma.xci
 # include ../common/vivado.mk
 # 
 ###################################################################
 # phony targets
 .PHONY: clean fpga
 # prevent make from deleting intermediate files and reports
 .PRECIOUS: %.xpr %.bit
 .SECONDARY:
 CONFIG ?= config.mk
 -include ../$(CONFIG)
 SYN_FILES_REL = $(patsubst %, ../%, $(SYN_FILES))
 INC_FILES_REL = $(patsubst %, ../%, $(INC_FILES))
 XCI_FILES_REL = $(patsubst %, ../%, $(XCI_FILES))
 ifdef XDC_FILES
  XDC_FILES_REL = $(patsubst %, ../%, $(XDC_FILES))
 else
  XDC_FILES_REL = $(FPGA_TOP).xdc
 endif
 ###################################################################
 # Main Targets
 #
 # all: build everything
 # clean: remove output files and project files
 ###################################################################
 all: fpga
 fpga: $(FPGA_TOP).bit
 tmpclean:
 	-rm -rf *.log *.jou *.cache *.hw *.ip_user_files *.runs *.xpr *.html *.xml *.sim *.srcs *.str .Xil defines.v
 	-rm -rf create_project.tcl run_synth.tcl run_impl.tcl generate_bit.tcl
 clean: tmpclean
 	-rm -rf *.bit program.tcl
 distclean: clean
 	-rm -rf rev
 ###################################################################
 # Target implementations
 ###################################################################
 # Vivado project file
 %.xpr: Makefile $(XCI_FILES_REL)
 	rm -rf defines.v
 	touch defines.v
 	for x in $(DEFS); do echo '`define' $$x >> defines.v; done
 	echo "create_project -force -part $(FPGA_PART) $*" > create_project.tcl
 	echo "add_files -fileset sources_1 defines.v" >> create_project.tcl
 	for x in $(SYN_FILES_REL); do echo "add_files -fileset sources_1 $$x" >> create_project.tcl; done
 	for x in $(XDC_FILES_REL); do echo "add_files -fileset constrs_1 $$x" >> create_project.tcl; done
 	for x in $(XCI_FILES_REL); do echo "import_ip $$x" >> create_project.tcl; done
 	echo "exit" >> create_project.tcl
 	vivado -mode batch -source create_project.tcl
 # synthesis run
 %.runs/synth_1/%.dcp: %.xpr $(SYN_FILES_REL) $(INC_FILES_REL) $(XDC_FILES_REL)
 	echo "open_project $*.xpr" > run_synth.tcl
 	echo "reset_run synth_1" >> run_synth.tcl
 	echo "launch_runs synth_1" >> run_synth.tcl
 	echo "wait_on_run synth_1" >> run_synth.tcl
 	echo "exit" >> run_synth.tcl
 	vivado -mode batch -source run_synth.tcl
 # implementation run
 %.runs/impl_1/%_routed.dcp: %.runs/synth_1/%.dcp
 	echo "open_project $*.xpr" > run_impl.tcl
 	echo "reset_run impl_1" >> run_impl.tcl
 	echo "launch_runs impl_1" >> run_impl.tcl
 	echo "wait_on_run impl_1" >> run_impl.tcl
 	echo "exit" >> run_impl.tcl
 	vivado -mode batch -source run_impl.tcl
 # bit file
 %.bit: %.runs/impl_1/%_routed.dcp
 	echo "open_project $*.xpr" > generate_bit.tcl
 	echo "open_run impl_1" >> generate_bit.tcl
 	echo "write_bitstream -force $*.bit" >> generate_bit.tcl
 	echo "exit" >> generate_bit.tcl
 	vivado -mode batch -source generate_bit.tcl
 	mkdir -p rev
 	EXT=bit; COUNT=100; \
 	while [ -e rev/$*_rev$$COUNT.$$EXT ]; \
 	do let COUNT=COUNT+1; done; \
 	cp $@ rev/$*_rev$$COUNT.$$EXT; \
 	echo "Output: rev/$*_rev$$COUNT.$$EXT";
--- a/example/KC705/fpga_gmii/fpga.xdc
+++ b/example/KC705/fpga_gmii/fpga.xdc
@ -0,0 +1,78 @@
 # XDC constraints for the Xilinx KC705 board
 # part: xc7k325tffg900-2
 # General configuration
 set_property CFGBVS VCCO [current_design]
 set_property CONFIG_VOLTAGE 2.5 [current_design]
 set_property BITSTREAM.GENERAL.COMPRESS true [current_design]
 # System clocks
 # 200 MHz
 set_property -dict {LOC AD12 IOSTANDARD LVDS} [get_ports clk_200mhz_p]
 set_property -dict {LOC AD11 IOSTANDARD LVDS} [get_ports clk_200mhz_n]
 create_clock -period 5.000 -name clk_200mhz [get_ports clk_200mhz_p]
 # LEDs
 set_property -dict {LOC AB8  IOSTANDARD LVCMOS15 SLEW SLOW DRIVE 12} [get_ports {led[0]}]
 set_property -dict {LOC AA8  IOSTANDARD LVCMOS15 SLEW SLOW DRIVE 12} [get_ports {led[1]}]
 set_property -dict {LOC AC9  IOSTANDARD LVCMOS15 SLEW SLOW DRIVE 12} [get_ports {led[2]}]
 set_property -dict {LOC AB9  IOSTANDARD LVCMOS15 SLEW SLOW DRIVE 12} [get_ports {led[3]}]
 set_property -dict {LOC AE26 IOSTANDARD LVCMOS25 SLEW SLOW DRIVE 12} [get_ports {led[4]}]
 set_property -dict {LOC G19  IOSTANDARD LVCMOS25 SLEW SLOW DRIVE 12} [get_ports {led[5]}]
 set_property -dict {LOC E18  IOSTANDARD LVCMOS25 SLEW SLOW DRIVE 12} [get_ports {led[6]}]
 set_property -dict {LOC F16  IOSTANDARD LVCMOS25 SLEW SLOW DRIVE 12} [get_ports {led[7]}]
 # Reset button
 set_property -dict {LOC AB7  IOSTANDARD LVCMOS15} [get_ports reset]
 # Push buttons
 set_property -dict {LOC AA12 IOSTANDARD LVCMOS15} [get_ports btnu]
 set_property -dict {LOC AC6  IOSTANDARD LVCMOS15} [get_ports btnl]
 set_property -dict {LOC AB12 IOSTANDARD LVCMOS15} [get_ports btnd]
 set_property -dict {LOC AG5  IOSTANDARD LVCMOS15} [get_ports btnr]
 set_property -dict {LOC G12  IOSTANDARD LVCMOS25} [get_ports btnc]
 # Toggle switches
 set_property -dict {LOC Y29  IOSTANDARD LVCMOS25} [get_ports {sw[0]}]
 set_property -dict {LOC W29  IOSTANDARD LVCMOS25} [get_ports {sw[1]}]
 set_property -dict {LOC AA28 IOSTANDARD LVCMOS25} [get_ports {sw[2]}]
 set_property -dict {LOC Y28  IOSTANDARD LVCMOS25} [get_ports {sw[3]}]
 # UART
 set_property -dict {LOC K24  IOSTANDARD LVCMOS25 SLEW SLOW DRIVE 12} [get_ports uart_txd]
 set_property -dict {LOC M19  IOSTANDARD LVCMOS25} [get_ports uart_rxd]
 set_property -dict {LOC L27  IOSTANDARD LVCMOS25 SLEW SLOW DRIVE 12} [get_ports uart_rts]
 set_property -dict {LOC K23  IOSTANDARD LVCMOS25} [get_ports uart_cts]
 # Gigabit Ethernet GMII PHY
 set_property -dict {LOC U27  IOSTANDARD LVCMOS25} [get_ports phy_rx_clk]
 set_property -dict {LOC U30  IOSTANDARD LVCMOS25} [get_ports {phy_rxd[0]}]
 set_property -dict {LOC U25  IOSTANDARD LVCMOS25} [get_ports {phy_rxd[1]}]
 set_property -dict {LOC T25  IOSTANDARD LVCMOS25} [get_ports {phy_rxd[2]}]
 set_property -dict {LOC U28  IOSTANDARD LVCMOS25} [get_ports {phy_rxd[3]}]
 set_property -dict {LOC R19  IOSTANDARD LVCMOS25} [get_ports {phy_rxd[4]}]
 set_property -dict {LOC T27  IOSTANDARD LVCMOS25} [get_ports {phy_rxd[5]}]
 set_property -dict {LOC T26  IOSTANDARD LVCMOS25} [get_ports {phy_rxd[6]}]
 set_property -dict {LOC T28  IOSTANDARD LVCMOS25} [get_ports {phy_rxd[7]}]
 set_property -dict {LOC R28  IOSTANDARD LVCMOS25} [get_ports phy_rx_dv]
 set_property -dict {LOC V26  IOSTANDARD LVCMOS25} [get_ports phy_rx_er]
 set_property -dict {LOC K30  IOSTANDARD LVCMOS25 SLEW FAST DRIVE 16} [get_ports phy_gtx_clk]
 set_property -dict {LOC M28  IOSTANDARD LVCMOS25} [get_ports phy_tx_clk]
 set_property -dict {LOC N27  IOSTANDARD LVCMOS25 SLEW FAST DRIVE 16} [get_ports {phy_txd[0]}]
 set_property -dict {LOC N25  IOSTANDARD LVCMOS25 SLEW FAST DRIVE 16} [get_ports {phy_txd[1]}]
 set_property -dict {LOC M29  IOSTANDARD LVCMOS25 SLEW FAST DRIVE 16} [get_ports {phy_txd[2]}]
 set_property -dict {LOC L28  IOSTANDARD LVCMOS25 SLEW FAST DRIVE 16} [get_ports {phy_txd[3]}]
 set_property -dict {LOC J26  IOSTANDARD LVCMOS25 SLEW FAST DRIVE 16} [get_ports {phy_txd[4]}]
 set_property -dict {LOC K26  IOSTANDARD LVCMOS25 SLEW FAST DRIVE 16} [get_ports {phy_txd[5]}]
 set_property -dict {LOC L30  IOSTANDARD LVCMOS25 SLEW FAST DRIVE 16} [get_ports {phy_txd[6]}]
 set_property -dict {LOC J28  IOSTANDARD LVCMOS25 SLEW FAST DRIVE 16} [get_ports {phy_txd[7]}]
 set_property -dict {LOC M27  IOSTANDARD LVCMOS25 SLEW FAST DRIVE 16} [get_ports phy_tx_en]
 set_property -dict {LOC N29  IOSTANDARD LVCMOS25 SLEW FAST DRIVE 16} [get_ports phy_tx_er]
 set_property -dict {LOC L20  IOSTANDARD LVCMOS25 SLEW SLOW DRIVE 12} [get_ports phy_reset_n]
 set_property -dict {LOC N30  IOSTANDARD LVCMOS25} [get_ports phy_int_n]
 #set_property -dict {LOC J21  IOSTANDARD LVCMOS25 SLEW SLOW DRIVE 12} [get_ports phy_mdio]
 #set_property -dict {LOC R23  IOSTANDARD LVCMOS25 SLEW SLOW DRIVE 12} [get_ports phy_mdc]
 create_clock -period 40.000 -name phy_tx_clk [get_ports phy_tx_clk]
 create_clock -period 8.000 -name phy_rx_clk [get_ports phy_rx_clk]
--- a/example/KC705/fpga_gmii/fpga/Makefile
+++ b/example/KC705/fpga_gmii/fpga/Makefile
@ -0,0 +1,65 @@
 # FPGA settings
 FPGA_PART = xc7k325tffg900-2
 FPGA_TOP = fpga
 FPGA_ARCH = kintex7
 # Files for synthesis
 SYN_FILES = rtl/fpga.v
 SYN_FILES += rtl/fpga_core.v
 SYN_FILES += rtl/debounce_switch.v
 SYN_FILES += rtl/sync_reset.v
 SYN_FILES += rtl/sync_signal.v
 SYN_FILES += lib/eth/rtl/oddr.v
 SYN_FILES += lib/eth/rtl/ssio_sdr_in.v
 SYN_FILES += lib/eth/rtl/ssio_sdr_out.v
 SYN_FILES += lib/eth/rtl/gmii_phy_if.v
 SYN_FILES += lib/eth/rtl/eth_mac_1g_gmii_fifo.v
 SYN_FILES += lib/eth/rtl/eth_mac_1g_gmii.v
 SYN_FILES += lib/eth/rtl/eth_mac_1g.v
 SYN_FILES += lib/eth/rtl/axis_gmii_rx.v
 SYN_FILES += lib/eth/rtl/axis_gmii_tx.v
 SYN_FILES += lib/eth/rtl/lfsr.v
 SYN_FILES += lib/eth/rtl/eth_axis_rx.v
 SYN_FILES += lib/eth/rtl/eth_axis_tx.v
 SYN_FILES += lib/eth/rtl/udp_complete.v
 SYN_FILES += lib/eth/rtl/udp_checksum_gen.v
 SYN_FILES += lib/eth/rtl/udp.v
 SYN_FILES += lib/eth/rtl/udp_ip_rx.v
 SYN_FILES += lib/eth/rtl/udp_ip_tx.v
 SYN_FILES += lib/eth/rtl/ip_complete.v
 SYN_FILES += lib/eth/rtl/ip.v
 SYN_FILES += lib/eth/rtl/ip_eth_rx.v
 SYN_FILES += lib/eth/rtl/ip_eth_tx.v
 SYN_FILES += lib/eth/rtl/ip_arb_mux.v
 SYN_FILES += lib/eth/rtl/arp.v
 SYN_FILES += lib/eth/rtl/arp_cache.v
 SYN_FILES += lib/eth/rtl/arp_eth_rx.v
 SYN_FILES += lib/eth/rtl/arp_eth_tx.v
 SYN_FILES += lib/eth/rtl/eth_arb_mux.v
 SYN_FILES += lib/eth/lib/axis/rtl/arbiter.v
 SYN_FILES += lib/eth/lib/axis/rtl/priority_encoder.v
 SYN_FILES += lib/eth/lib/axis/rtl/axis_fifo.v
 SYN_FILES += lib/eth/lib/axis/rtl/axis_async_fifo.v
 # XDC files
 XDC_FILES = fpga.xdc
 XDC_FILES += clock.xdc
 XDC_FILES += lib/eth/syn/gmii_phy_if.tcl
 XDC_FILES += lib/eth/syn/eth_mac_1g_gmii.tcl
 XDC_FILES += lib/eth/syn/eth_mac_fifo.tcl
 XDC_FILES += lib/eth/lib/axis/syn/axis_async_fifo.tcl
 include ../common/vivado.mk
 program: $(FPGA_TOP).bit
 	echo "open_hw" > program.tcl
 	echo "connect_hw_server" >> program.tcl
 	echo "open_hw_target" >> program.tcl
 	echo "current_hw_device [lindex [get_hw_devices] 0]" >> program.tcl
 	echo "refresh_hw_device -update_hw_probes false [lindex [get_hw_devices] 0]" >> program.tcl
 	echo "set_property PROGRAM.FILE {$(FPGA_TOP).bit} [lindex [get_hw_devices] 0]" >> program.tcl
 	echo "program_hw_devices [lindex [get_hw_devices] 0]" >> program.tcl
 	echo "exit" >> program.tcl
 	vivado -mode batch -source program.tcl
--- a/example/KC705/fpga_gmii/lib/eth
+++ b/example/KC705/fpga_gmii/lib/eth
@ -0,0 +1 @@
 ../../../../
--- a/example/KC705/fpga_gmii/rtl/debounce_switch.v
+++ b/example/KC705/fpga_gmii/rtl/debounce_switch.v
@ -0,0 +1,89 @@
 /*
 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
 `timescale 1 ns / 1 ps
 /*
 * Synchronizes switch and button inputs with a slow sampled shift register
 */
 module debounce_switch  #(
    parameter WIDTH=1, // width of the input and output signals
    parameter N=3, // length of shift register
    parameter RATE=125000 // clock division factor
 )(
    input wire clk,
    input wire rst,
    input wire [WIDTH-1:0] in,
    output wire [WIDTH-1:0] out
 );
 reg [23:0] cnt_reg = 24'd0;
 reg [N-1:0] debounce_reg[WIDTH-1:0];
 reg [WIDTH-1:0] state;
 /*
 * The synchronized output is the state register
 */
 assign out = state;
 integer k;
 always @(posedge clk or posedge rst) begin
    if (rst) begin
        cnt_reg <= 0;
        state <= 0;
        for (k = 0; k < WIDTH; k = k + 1) begin
            debounce_reg[k] <= 0;
        end
    end else begin
        if (cnt_reg < RATE) begin
            cnt_reg <= cnt_reg + 24'd1;
        end else begin
            cnt_reg <= 24'd0;
        end
        if (cnt_reg == 24'd0) begin
            for (k = 0; k < WIDTH; k = k + 1) begin
                debounce_reg[k] <= {debounce_reg[k][N-2:0], in[k]};
            end
        end
        for (k = 0; k < WIDTH; k = k + 1) begin
            if (|debounce_reg[k] == 0) begin
                state[k] <= 0;
            end else if (&debounce_reg[k] == 1) begin
                state[k] <= 1;
            end else begin
                state[k] <= state[k];
            end
        end
    end
 end
 endmodule
--- a/example/KC705/fpga_gmii/rtl/fpga.v
+++ b/example/KC705/fpga_gmii/rtl/fpga.v
@ -0,0 +1,254 @@
 /*
 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
 `timescale 1ns / 1ps
 /*
 * 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 GMII
     */
    input  wire       phy_rx_clk,
    input  wire [7:0] phy_rxd,
    input  wire       phy_rx_dv,
    input  wire       phy_rx_er,
    output wire       phy_gtx_clk,
    input  wire       phy_tx_clk,
    output wire [7:0] phy_txd,
    output wire       phy_tx_en,
    output wire       phy_tx_er,
    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;
 wire clk_200mhz_bufg;
 wire clk_200mhz_mmcm_out;
 // Internal 125 MHz clock
 wire clk_200mhz_int;
 wire rst_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
 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(0),
    .CLKOUT2_DIVIDE(1),
    .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(),
    .CLKOUT1B(),
    .CLKOUT2(),
    .CLKOUT2B(),
    .CLKOUT3(),
    .CLKOUT3B(),
    .CLKOUT4(),
    .CLKOUT5(),
    .CLKOUT6(),
    .CLKFBOUT(mmcm_clkfb),
    .CLKFBOUTB(),
    .LOCKED(mmcm_locked)
 );
 BUFG
 clk_bufg_inst (
    .I(clk_mmcm_out),
    .O(clk_int)
 );
 sync_reset #(
    .N(4)
 )
 sync_reset_inst (
    .clk(clk_int),
    .rst(~mmcm_locked),
    .sync_reset_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})
 );
 fpga_core
 core_inst (
    /*
     * Clock: 125MHz
     * Synchronous reset
     */
    .clk(clk_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 GMII
     */
    .phy_rx_clk(phy_rx_clk),
    .phy_rxd(phy_rxd),
    .phy_rx_dv(phy_rx_dv),
    .phy_rx_er(phy_rx_er),
    .phy_gtx_clk(phy_gtx_clk),
    .phy_tx_clk(phy_tx_clk),
    .phy_txd(phy_txd),
    .phy_tx_en(phy_tx_en),
    .phy_tx_er(phy_tx_er),
    .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
--- a/example/KC705/fpga_gmii/rtl/fpga_core.v
+++ b/example/KC705/fpga_gmii/rtl/fpga_core.v
@ -0,0 +1,587 @@
 /*
 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
 `timescale 1ns / 1ps
 /*
 * FPGA core logic
 */
 module fpga_core #
 (
    parameter TARGET = "XILINX"
 )
 (
    /*
     * Clock: 125MHz
     * Synchronous reset
     */
    input  wire       clk,
    input  wire       rst,
    /*
     * GPIO
     */
    input  wire       btnu,
    input  wire       btnl,
    input  wire       btnd,
    input  wire       btnr,
    input  wire       btnc,
    input  wire [7:0] sw,
    output wire [7:0] led,
    /*
     * Ethernet: 1000BASE-T GMII
     */
    input  wire       phy_rx_clk,
    input  wire [7:0] phy_rxd,
    input  wire       phy_rx_dv,
    input  wire       phy_rx_er,
    output wire       phy_gtx_clk,
    input  wire       phy_tx_clk,
    output wire [7:0] phy_txd,
    output wire       phy_tx_en,
    output wire       phy_tx_er,
    output wire       phy_reset_n,
    input  wire       phy_int_n,
    /*
     * UART: 115200 bps, 8N1
     */
    input  wire       uart_rxd,
    output wire       uart_txd,
    output wire       uart_rts,
    input  wire       uart_cts
 );
 // AXI between MAC and Ethernet modules
 wire [7:0] rx_axis_tdata;
 wire rx_axis_tvalid;
 wire rx_axis_tready;
 wire rx_axis_tlast;
 wire rx_axis_tuser;
 wire [7:0] tx_axis_tdata;
 wire tx_axis_tvalid;
 wire tx_axis_tready;
 wire tx_axis_tlast;
 wire tx_axis_tuser;
 // Ethernet frame between Ethernet modules and UDP stack
 wire rx_eth_hdr_ready;
 wire rx_eth_hdr_valid;
 wire [47:0] rx_eth_dest_mac;
 wire [47:0] rx_eth_src_mac;
 wire [15:0] rx_eth_type;
 wire [7:0] rx_eth_payload_axis_tdata;
 wire rx_eth_payload_axis_tvalid;
 wire rx_eth_payload_axis_tready;
 wire rx_eth_payload_axis_tlast;
 wire rx_eth_payload_axis_tuser;
 wire tx_eth_hdr_ready;
 wire tx_eth_hdr_valid;
 wire [47:0] tx_eth_dest_mac;
 wire [47:0] tx_eth_src_mac;
 wire [15:0] tx_eth_type;
 wire [7:0] tx_eth_payload_axis_tdata;
 wire tx_eth_payload_axis_tvalid;
 wire tx_eth_payload_axis_tready;
 wire tx_eth_payload_axis_tlast;
 wire tx_eth_payload_axis_tuser;
 // IP frame connections
 wire rx_ip_hdr_valid;
 wire rx_ip_hdr_ready;
 wire [47:0] rx_ip_eth_dest_mac;
 wire [47:0] rx_ip_eth_src_mac;
 wire [15:0] rx_ip_eth_type;
 wire [3:0] rx_ip_version;
 wire [3:0] rx_ip_ihl;
 wire [5:0] rx_ip_dscp;
 wire [1:0] rx_ip_ecn;
 wire [15:0] rx_ip_length;
 wire [15:0] rx_ip_identification;
 wire [2:0] rx_ip_flags;
 wire [12:0] rx_ip_fragment_offset;
 wire [7:0] rx_ip_ttl;
 wire [7:0] rx_ip_protocol;
 wire [15:0] rx_ip_header_checksum;
 wire [31:0] rx_ip_source_ip;
 wire [31:0] rx_ip_dest_ip;
 wire [7:0] rx_ip_payload_axis_tdata;
 wire rx_ip_payload_axis_tvalid;
 wire rx_ip_payload_axis_tready;
 wire rx_ip_payload_axis_tlast;
 wire rx_ip_payload_axis_tuser;
 wire tx_ip_hdr_valid;
 wire tx_ip_hdr_ready;
 wire [5:0] tx_ip_dscp;
 wire [1:0] tx_ip_ecn;
 wire [15:0] tx_ip_length;
 wire [7:0] tx_ip_ttl;
 wire [7:0] tx_ip_protocol;
 wire [31:0] tx_ip_source_ip;
 wire [31:0] tx_ip_dest_ip;
 wire [7:0] tx_ip_payload_axis_tdata;
 wire tx_ip_payload_axis_tvalid;
 wire tx_ip_payload_axis_tready;
 wire tx_ip_payload_axis_tlast;
 wire tx_ip_payload_axis_tuser;
 // UDP frame connections
 wire rx_udp_hdr_valid;
 wire rx_udp_hdr_ready;
 wire [47:0] rx_udp_eth_dest_mac;
 wire [47:0] rx_udp_eth_src_mac;
 wire [15:0] rx_udp_eth_type;
 wire [3:0] rx_udp_ip_version;
 wire [3:0] rx_udp_ip_ihl;
 wire [5:0] rx_udp_ip_dscp;
 wire [1:0] rx_udp_ip_ecn;
 wire [15:0] rx_udp_ip_length;
 wire [15:0] rx_udp_ip_identification;
 wire [2:0] rx_udp_ip_flags;
 wire [12:0] rx_udp_ip_fragment_offset;
 wire [7:0] rx_udp_ip_ttl;
 wire [7:0] rx_udp_ip_protocol;
 wire [15:0] rx_udp_ip_header_checksum;
 wire [31:0] rx_udp_ip_source_ip;
 wire [31:0] rx_udp_ip_dest_ip;
 wire [15:0] rx_udp_source_port;
 wire [15:0] rx_udp_dest_port;
 wire [15:0] rx_udp_length;
 wire [15:0] rx_udp_checksum;
 wire [7:0] rx_udp_payload_axis_tdata;
 wire rx_udp_payload_axis_tvalid;
 wire rx_udp_payload_axis_tready;
 wire rx_udp_payload_axis_tlast;
 wire rx_udp_payload_axis_tuser;
 wire tx_udp_hdr_valid;
 wire tx_udp_hdr_ready;
 wire [5:0] tx_udp_ip_dscp;
 wire [1:0] tx_udp_ip_ecn;
 wire [7:0] tx_udp_ip_ttl;
 wire [31:0] tx_udp_ip_source_ip;
 wire [31:0] tx_udp_ip_dest_ip;
 wire [15:0] tx_udp_source_port;
 wire [15:0] tx_udp_dest_port;
 wire [15:0] tx_udp_length;
 wire [15:0] tx_udp_checksum;
 wire [7:0] tx_udp_payload_axis_tdata;
 wire tx_udp_payload_axis_tvalid;
 wire tx_udp_payload_axis_tready;
 wire tx_udp_payload_axis_tlast;
 wire tx_udp_payload_axis_tuser;
 wire [7:0] rx_fifo_udp_payload_axis_tdata;
 wire rx_fifo_udp_payload_axis_tvalid;
 wire rx_fifo_udp_payload_axis_tready;
 wire rx_fifo_udp_payload_axis_tlast;
 wire rx_fifo_udp_payload_axis_tuser;
 wire [7:0] tx_fifo_udp_payload_axis_tdata;
 wire tx_fifo_udp_payload_axis_tvalid;
 wire tx_fifo_udp_payload_axis_tready;
 wire tx_fifo_udp_payload_axis_tlast;
 wire tx_fifo_udp_payload_axis_tuser;
 // Configuration
 wire [47:0] local_mac   = 48'h02_00_00_00_00_00;
 wire [31:0] local_ip    = {8'd192, 8'd168, 8'd1,   8'd128};
 wire [31:0] gateway_ip  = {8'd192, 8'd168, 8'd1,   8'd1};
 wire [31:0] subnet_mask = {8'd255, 8'd255, 8'd255, 8'd0};
 // IP ports not used
 assign rx_ip_hdr_ready = 1;
 assign rx_ip_payload_axis_tready = 1;
 assign tx_ip_hdr_valid = 0;
 assign tx_ip_dscp = 0;
 assign tx_ip_ecn = 0;
 assign tx_ip_length = 0;
 assign tx_ip_ttl = 0;
 assign tx_ip_protocol = 0;
 assign tx_ip_source_ip = 0;
 assign tx_ip_dest_ip = 0;
 assign tx_ip_payload_axis_tdata = 0;
 assign tx_ip_payload_axis_tvalid = 0;
 assign tx_ip_payload_axis_tlast = 0;
 assign tx_ip_payload_axis_tuser = 0;
 // Loop back UDP
 wire match_cond = rx_udp_dest_port == 1234;
 wire no_match = !match_cond;
 reg match_cond_reg = 0;
 reg no_match_reg = 0;
 always @(posedge clk) begin
    if (rst) begin
        match_cond_reg <= 0;
        no_match_reg <= 0;
    end else begin
        if (rx_udp_payload_axis_tvalid) begin
            if ((!match_cond_reg && !no_match_reg) ||
                (rx_udp_payload_axis_tvalid && rx_udp_payload_axis_tready && rx_udp_payload_axis_tlast)) begin
                match_cond_reg <= match_cond;
                no_match_reg <= no_match;
            end
        end else begin
            match_cond_reg <= 0;
            no_match_reg <= 0;
        end
    end
 end
 assign tx_udp_hdr_valid = rx_udp_hdr_valid && match_cond;
 assign rx_udp_hdr_ready = (tx_eth_hdr_ready && match_cond) || no_match;
 assign tx_udp_ip_dscp = 0;
 assign tx_udp_ip_ecn = 0;
 assign tx_udp_ip_ttl = 64;
 assign tx_udp_ip_source_ip = local_ip;
 assign tx_udp_ip_dest_ip = rx_udp_ip_source_ip;
 assign tx_udp_source_port = rx_udp_dest_port;
 assign tx_udp_dest_port = rx_udp_source_port;
 assign tx_udp_length = rx_udp_length;
 assign tx_udp_checksum = 0;
 assign tx_udp_payload_axis_tdata = tx_fifo_udp_payload_axis_tdata;
 assign tx_udp_payload_axis_tvalid = tx_fifo_udp_payload_axis_tvalid;
 assign tx_fifo_udp_payload_axis_tready = tx_udp_payload_axis_tready;
 assign tx_udp_payload_axis_tlast = tx_fifo_udp_payload_axis_tlast;
 assign tx_udp_payload_axis_tuser = tx_fifo_udp_payload_axis_tuser;
 assign rx_fifo_udp_payload_axis_tdata = rx_udp_payload_axis_tdata;
 assign rx_fifo_udp_payload_axis_tvalid = rx_udp_payload_axis_tvalid && match_cond_reg;
 assign rx_udp_payload_axis_tready = (rx_fifo_udp_payload_axis_tready && match_cond_reg) || no_match_reg;
 assign rx_fifo_udp_payload_axis_tlast = rx_udp_payload_axis_tlast;
 assign rx_fifo_udp_payload_axis_tuser = rx_udp_payload_axis_tuser;
 // Place first payload byte onto LEDs
 reg valid_last = 0;
 reg [7:0] led_reg = 0;
 always @(posedge clk) begin
    if (rst) begin
        led_reg <= 0;
    end else begin
        if (tx_udp_payload_axis_tvalid) begin
            if (!valid_last) begin
                led_reg <= tx_udp_payload_axis_tdata;
                valid_last <= 1'b1;
            end
            if (tx_udp_payload_axis_tlast) begin
                valid_last <= 1'b0;
            end
        end
    end
 end
 //assign led = sw;
 assign led = led_reg;
 assign phy_reset_n = !rst;
 assign uart_txd = 0;
 assign uart_rts = 0;
 eth_mac_1g_gmii_fifo #(
    .TARGET(TARGET),
    .IODDR_STYLE("IODDR"),
    .CLOCK_INPUT_STYLE("BUFR"),
    .ENABLE_PADDING(1),
    .MIN_FRAME_LENGTH(64),
    .TX_FIFO_ADDR_WIDTH(12),
    .TX_FRAME_FIFO(1),
    .RX_FIFO_ADDR_WIDTH(12),
    .RX_FRAME_FIFO(1)
 )
 eth_mac_inst (
    .gtx_clk(clk),
    .gtx_rst(rst),
    .logic_clk(clk),
    .logic_rst(rst),
    .tx_axis_tdata(tx_axis_tdata),
    .tx_axis_tvalid(tx_axis_tvalid),
    .tx_axis_tready(tx_axis_tready),
    .tx_axis_tlast(tx_axis_tlast),
    .tx_axis_tuser(tx_axis_tuser),
    .rx_axis_tdata(rx_axis_tdata),
    .rx_axis_tvalid(rx_axis_tvalid),
    .rx_axis_tready(rx_axis_tready),
    .rx_axis_tlast(rx_axis_tlast),
    .rx_axis_tuser(rx_axis_tuser),
    .gmii_rx_clk(phy_rx_clk),
    .gmii_rxd(phy_rxd),
    .gmii_rx_dv(phy_rx_dv),
    .gmii_rx_er(phy_rx_er),
    .gmii_tx_clk(phy_gtx_clk),
    .mii_tx_clk(phy_tx_clk),
    .gmii_txd(phy_txd),
    .gmii_tx_en(phy_tx_en),
    .gmii_tx_er(phy_tx_er),
    .tx_fifo_overflow(),
    .tx_fifo_bad_frame(),
    .tx_fifo_good_frame(),
    .rx_error_bad_frame(),
    .rx_error_bad_fcs(),
    .rx_fifo_overflow(),
    .rx_fifo_bad_frame(),
    .rx_fifo_good_frame(),
    .speed(),
    .ifg_delay(12)
 );
 eth_axis_rx
 eth_axis_rx_inst (
    .clk(clk),
    .rst(rst),
    // AXI input
    .s_axis_tdata(rx_axis_tdata),
    .s_axis_tvalid(rx_axis_tvalid),
    .s_axis_tready(rx_axis_tready),
    .s_axis_tlast(rx_axis_tlast),
    .s_axis_tuser(rx_axis_tuser),
    // Ethernet frame output
    .m_eth_hdr_valid(rx_eth_hdr_valid),
    .m_eth_hdr_ready(rx_eth_hdr_ready),
    .m_eth_dest_mac(rx_eth_dest_mac),
    .m_eth_src_mac(rx_eth_src_mac),
    .m_eth_type(rx_eth_type),
    .m_eth_payload_axis_tdata(rx_eth_payload_axis_tdata),
    .m_eth_payload_axis_tvalid(rx_eth_payload_axis_tvalid),
    .m_eth_payload_axis_tready(rx_eth_payload_axis_tready),
    .m_eth_payload_axis_tlast(rx_eth_payload_axis_tlast),
    .m_eth_payload_axis_tuser(rx_eth_payload_axis_tuser),
    // Status signals
    .busy(),
    .error_header_early_termination()
 );
 eth_axis_tx
 eth_axis_tx_inst (
    .clk(clk),
    .rst(rst),
    // Ethernet frame input
    .s_eth_hdr_valid(tx_eth_hdr_valid),
    .s_eth_hdr_ready(tx_eth_hdr_ready),
    .s_eth_dest_mac(tx_eth_dest_mac),
    .s_eth_src_mac(tx_eth_src_mac),
    .s_eth_type(tx_eth_type),
    .s_eth_payload_axis_tdata(tx_eth_payload_axis_tdata),
    .s_eth_payload_axis_tvalid(tx_eth_payload_axis_tvalid),
    .s_eth_payload_axis_tready(tx_eth_payload_axis_tready),
    .s_eth_payload_axis_tlast(tx_eth_payload_axis_tlast),
    .s_eth_payload_axis_tuser(tx_eth_payload_axis_tuser),
    // AXI output
    .m_axis_tdata(tx_axis_tdata),
    .m_axis_tvalid(tx_axis_tvalid),
    .m_axis_tready(tx_axis_tready),
    .m_axis_tlast(tx_axis_tlast),
    .m_axis_tuser(tx_axis_tuser),
    // Status signals
    .busy()
 );
 udp_complete
 udp_complete_inst (
    .clk(clk),
    .rst(rst),
    // Ethernet frame input
    .s_eth_hdr_valid(rx_eth_hdr_valid),
    .s_eth_hdr_ready(rx_eth_hdr_ready),
    .s_eth_dest_mac(rx_eth_dest_mac),
    .s_eth_src_mac(rx_eth_src_mac),
    .s_eth_type(rx_eth_type),
    .s_eth_payload_axis_tdata(rx_eth_payload_axis_tdata),
    .s_eth_payload_axis_tvalid(rx_eth_payload_axis_tvalid),
    .s_eth_payload_axis_tready(rx_eth_payload_axis_tready),
    .s_eth_payload_axis_tlast(rx_eth_payload_axis_tlast),
    .s_eth_payload_axis_tuser(rx_eth_payload_axis_tuser),
    // Ethernet frame output
    .m_eth_hdr_valid(tx_eth_hdr_valid),
    .m_eth_hdr_ready(tx_eth_hdr_ready),
    .m_eth_dest_mac(tx_eth_dest_mac),
    .m_eth_src_mac(tx_eth_src_mac),
    .m_eth_type(tx_eth_type),
    .m_eth_payload_axis_tdata(tx_eth_payload_axis_tdata),
    .m_eth_payload_axis_tvalid(tx_eth_payload_axis_tvalid),
    .m_eth_payload_axis_tready(tx_eth_payload_axis_tready),
    .m_eth_payload_axis_tlast(tx_eth_payload_axis_tlast),
    .m_eth_payload_axis_tuser(tx_eth_payload_axis_tuser),
    // IP frame input
    .s_ip_hdr_valid(tx_ip_hdr_valid),
    .s_ip_hdr_ready(tx_ip_hdr_ready),
    .s_ip_dscp(tx_ip_dscp),
    .s_ip_ecn(tx_ip_ecn),
    .s_ip_length(tx_ip_length),
    .s_ip_ttl(tx_ip_ttl),
    .s_ip_protocol(tx_ip_protocol),
    .s_ip_source_ip(tx_ip_source_ip),
    .s_ip_dest_ip(tx_ip_dest_ip),
    .s_ip_payload_axis_tdata(tx_ip_payload_axis_tdata),
    .s_ip_payload_axis_tvalid(tx_ip_payload_axis_tvalid),
    .s_ip_payload_axis_tready(tx_ip_payload_axis_tready),
    .s_ip_payload_axis_tlast(tx_ip_payload_axis_tlast),
    .s_ip_payload_axis_tuser(tx_ip_payload_axis_tuser),
    // IP frame output
    .m_ip_hdr_valid(rx_ip_hdr_valid),
    .m_ip_hdr_ready(rx_ip_hdr_ready),
    .m_ip_eth_dest_mac(rx_ip_eth_dest_mac),
    .m_ip_eth_src_mac(rx_ip_eth_src_mac),
    .m_ip_eth_type(rx_ip_eth_type),
    .m_ip_version(rx_ip_version),
    .m_ip_ihl(rx_ip_ihl),
    .m_ip_dscp(rx_ip_dscp),
    .m_ip_ecn(rx_ip_ecn),
    .m_ip_length(rx_ip_length),
    .m_ip_identification(rx_ip_identification),
    .m_ip_flags(rx_ip_flags),
    .m_ip_fragment_offset(rx_ip_fragment_offset),
    .m_ip_ttl(rx_ip_ttl),
    .m_ip_protocol(rx_ip_protocol),
    .m_ip_header_checksum(rx_ip_header_checksum),
    .m_ip_source_ip(rx_ip_source_ip),
    .m_ip_dest_ip(rx_ip_dest_ip),
    .m_ip_payload_axis_tdata(rx_ip_payload_axis_tdata),
    .m_ip_payload_axis_tvalid(rx_ip_payload_axis_tvalid),
    .m_ip_payload_axis_tready(rx_ip_payload_axis_tready),
    .m_ip_payload_axis_tlast(rx_ip_payload_axis_tlast),
    .m_ip_payload_axis_tuser(rx_ip_payload_axis_tuser),
    // UDP frame input
    .s_udp_hdr_valid(tx_udp_hdr_valid),
    .s_udp_hdr_ready(tx_udp_hdr_ready),
    .s_udp_ip_dscp(tx_udp_ip_dscp),
    .s_udp_ip_ecn(tx_udp_ip_ecn),
    .s_udp_ip_ttl(tx_udp_ip_ttl),
    .s_udp_ip_source_ip(tx_udp_ip_source_ip),
    .s_udp_ip_dest_ip(tx_udp_ip_dest_ip),
    .s_udp_source_port(tx_udp_source_port),
    .s_udp_dest_port(tx_udp_dest_port),
    .s_udp_length(tx_udp_length),
    .s_udp_checksum(tx_udp_checksum),
    .s_udp_payload_axis_tdata(tx_udp_payload_axis_tdata),
    .s_udp_payload_axis_tvalid(tx_udp_payload_axis_tvalid),
    .s_udp_payload_axis_tready(tx_udp_payload_axis_tready),
    .s_udp_payload_axis_tlast(tx_udp_payload_axis_tlast),
    .s_udp_payload_axis_tuser(tx_udp_payload_axis_tuser),
    // UDP frame output
    .m_udp_hdr_valid(rx_udp_hdr_valid),
    .m_udp_hdr_ready(rx_udp_hdr_ready),
    .m_udp_eth_dest_mac(rx_udp_eth_dest_mac),
    .m_udp_eth_src_mac(rx_udp_eth_src_mac),
    .m_udp_eth_type(rx_udp_eth_type),
    .m_udp_ip_version(rx_udp_ip_version),
    .m_udp_ip_ihl(rx_udp_ip_ihl),
    .m_udp_ip_dscp(rx_udp_ip_dscp),
    .m_udp_ip_ecn(rx_udp_ip_ecn),
    .m_udp_ip_length(rx_udp_ip_length),
    .m_udp_ip_identification(rx_udp_ip_identification),
    .m_udp_ip_flags(rx_udp_ip_flags),
    .m_udp_ip_fragment_offset(rx_udp_ip_fragment_offset),
    .m_udp_ip_ttl(rx_udp_ip_ttl),
    .m_udp_ip_protocol(rx_udp_ip_protocol),
    .m_udp_ip_header_checksum(rx_udp_ip_header_checksum),
    .m_udp_ip_source_ip(rx_udp_ip_source_ip),
    .m_udp_ip_dest_ip(rx_udp_ip_dest_ip),
    .m_udp_source_port(rx_udp_source_port),
    .m_udp_dest_port(rx_udp_dest_port),
    .m_udp_length(rx_udp_length),
    .m_udp_checksum(rx_udp_checksum),
    .m_udp_payload_axis_tdata(rx_udp_payload_axis_tdata),
    .m_udp_payload_axis_tvalid(rx_udp_payload_axis_tvalid),
    .m_udp_payload_axis_tready(rx_udp_payload_axis_tready),
    .m_udp_payload_axis_tlast(rx_udp_payload_axis_tlast),
    .m_udp_payload_axis_tuser(rx_udp_payload_axis_tuser),
    // Status signals
    .ip_rx_busy(),
    .ip_tx_busy(),
    .udp_rx_busy(),
    .udp_tx_busy(),
    .ip_rx_error_header_early_termination(),
    .ip_rx_error_payload_early_termination(),
    .ip_rx_error_invalid_header(),
    .ip_rx_error_invalid_checksum(),
    .ip_tx_error_payload_early_termination(),
    .ip_tx_error_arp_failed(),
    .udp_rx_error_header_early_termination(),
    .udp_rx_error_payload_early_termination(),
    .udp_tx_error_payload_early_termination(),
    // Configuration
    .local_mac(local_mac),
    .local_ip(local_ip),
    .gateway_ip(gateway_ip),
    .subnet_mask(subnet_mask),
    .clear_arp_cache(0)
 );
 axis_fifo #(
    .ADDR_WIDTH(12),
    .DATA_WIDTH(8),
    .KEEP_ENABLE(0),
    .ID_ENABLE(0),
    .DEST_ENABLE(0),
    .USER_ENABLE(1),
    .USER_WIDTH(1),
    .FRAME_FIFO(0)
 )
 udp_payload_fifo (
    .clk(clk),
    .rst(rst),
    // AXI input
    .s_axis_tdata(rx_fifo_udp_payload_axis_tdata),
    .s_axis_tkeep(0),
    .s_axis_tvalid(rx_fifo_udp_payload_axis_tvalid),
    .s_axis_tready(rx_fifo_udp_payload_axis_tready),
    .s_axis_tlast(rx_fifo_udp_payload_axis_tlast),
    .s_axis_tid(0),
    .s_axis_tdest(0),
    .s_axis_tuser(rx_fifo_udp_payload_axis_tuser),
    // AXI output
    .m_axis_tdata(tx_fifo_udp_payload_axis_tdata),
    .m_axis_tkeep(),
    .m_axis_tvalid(tx_fifo_udp_payload_axis_tvalid),
    .m_axis_tready(tx_fifo_udp_payload_axis_tready),
    .m_axis_tlast(tx_fifo_udp_payload_axis_tlast),
    .m_axis_tid(),
    .m_axis_tdest(),
    .m_axis_tuser(tx_fifo_udp_payload_axis_tuser),
    // Status
    .status_overflow(),
    .status_bad_frame(),
    .status_good_frame()
 );
 endmodule
--- a/example/KC705/fpga_gmii/rtl/sync_reset.v
+++ b/example/KC705/fpga_gmii/rtl/sync_reset.v
@ -0,0 +1,52 @@
 /*
 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
 `timescale 1 ns / 1 ps
 /*
 * Synchronizes an active-high asynchronous reset signal to a given clock by
 * using a pipeline of N registers.
 */
 module sync_reset #(
    parameter N=2 // depth of synchronizer
 )(
    input wire clk,
    input wire rst,
    output wire sync_reset_out
 );
 reg [N-1:0] sync_reg = {N{1'b1}};
 assign sync_reset_out = sync_reg[N-1];
 always @(posedge clk or posedge rst) begin
    if (rst)
        sync_reg <= {N{1'b1}};
    else
        sync_reg <= {sync_reg[N-2:0], 1'b0};
 end
 endmodule
--- a/example/KC705/fpga_gmii/rtl/sync_signal.v
+++ b/example/KC705/fpga_gmii/rtl/sync_signal.v
@ -0,0 +1,58 @@
 /*
 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
 `timescale 1 ns / 1 ps
 /*
 * Synchronizes an asyncronous signal to a given clock by using a pipeline of
 * two registers.
 */
 module sync_signal #(
    parameter WIDTH=1, // width of the input and output signals
    parameter N=2 // depth of synchronizer
 )(
    input wire clk,
    input wire [WIDTH-1:0] in,
    output wire [WIDTH-1:0] out
 );
 reg [WIDTH-1:0] sync_reg[N-1:0];
 /*
 * The synchronized output is the last register in the pipeline.
 */
 assign out = sync_reg[N-1];
 integer k;
 always @(posedge clk) begin
    sync_reg[0] <= in;
    for (k = 1; k < N; k = k + 1) begin
        sync_reg[k] <= sync_reg[k-1];
    end
 end
 endmodule
--- a/example/KC705/fpga_gmii/tb/arp_ep.py
+++ b/example/KC705/fpga_gmii/tb/arp_ep.py
@ -0,0 +1 @@
 ../lib/eth/tb/arp_ep.py
--- a/example/KC705/fpga_gmii/tb/axis_ep.py
+++ b/example/KC705/fpga_gmii/tb/axis_ep.py
@ -0,0 +1 @@
 ../lib/eth/tb/axis_ep.py
--- a/example/KC705/fpga_gmii/tb/eth_ep.py
+++ b/example/KC705/fpga_gmii/tb/eth_ep.py
@ -0,0 +1 @@
 ../lib/eth/tb/eth_ep.py
--- a/example/KC705/fpga_gmii/tb/gmii_ep.py
+++ b/example/KC705/fpga_gmii/tb/gmii_ep.py
@ -0,0 +1 @@
 ../lib/eth/tb/gmii_ep.py
--- a/example/KC705/fpga_gmii/tb/ip_ep.py
+++ b/example/KC705/fpga_gmii/tb/ip_ep.py
@ -0,0 +1 @@
 ../lib/eth/tb/ip_ep.py
--- a/example/KC705/fpga_gmii/tb/test_fpga_core.py
+++ b/example/KC705/fpga_gmii/tb/test_fpga_core.py
@ -0,0 +1,315 @@
 #!/usr/bin/env python
 """
 Copyright (c) 2015-2018 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.
 """
 from myhdl import *
 import os
 import eth_ep
 import arp_ep
 import udp_ep
 import gmii_ep
 module = 'fpga_core'
 testbench = 'test_%s' % module
 srcs = []
 srcs.append("../rtl/%s.v" % module)
 srcs.append("../lib/eth/rtl/oddr.v")
 srcs.append("../lib/eth/rtl/ssio_sdr_in.v")
 srcs.append("../lib/eth/rtl/ssio_sdr_out.v")
 srcs.append("../lib/eth/rtl/gmii_phy_if.v")
 srcs.append("../lib/eth/rtl/eth_mac_1g_gmii_fifo.v")
 srcs.append("../lib/eth/rtl/eth_mac_1g_gmii.v")
 srcs.append("../lib/eth/rtl/eth_mac_1g.v")
 srcs.append("../lib/eth/rtl/axis_gmii_rx.v")
 srcs.append("../lib/eth/rtl/axis_gmii_tx.v")
 srcs.append("../lib/eth/rtl/lfsr.v")
 srcs.append("../lib/eth/rtl/eth_axis_rx.v")
 srcs.append("../lib/eth/rtl/eth_axis_tx.v")
 srcs.append("../lib/eth/rtl/udp_complete.v")
 srcs.append("../lib/eth/rtl/udp_checksum_gen.v")
 srcs.append("../lib/eth/rtl/udp.v")
 srcs.append("../lib/eth/rtl/udp_ip_rx.v")
 srcs.append("../lib/eth/rtl/udp_ip_tx.v")
 srcs.append("../lib/eth/rtl/ip_complete.v")
 srcs.append("../lib/eth/rtl/ip.v")
 srcs.append("../lib/eth/rtl/ip_eth_rx.v")
 srcs.append("../lib/eth/rtl/ip_eth_tx.v")
 srcs.append("../lib/eth/rtl/ip_arb_mux.v")
 srcs.append("../lib/eth/rtl/arp.v")
 srcs.append("../lib/eth/rtl/arp_cache.v")
 srcs.append("../lib/eth/rtl/arp_eth_rx.v")
 srcs.append("../lib/eth/rtl/arp_eth_tx.v")
 srcs.append("../lib/eth/rtl/eth_arb_mux.v")
 srcs.append("../lib/eth/lib/axis/rtl/arbiter.v")
 srcs.append("../lib/eth/lib/axis/rtl/priority_encoder.v")
 srcs.append("../lib/eth/lib/axis/rtl/axis_fifo.v")
 srcs.append("../lib/eth/lib/axis/rtl/axis_async_fifo.v")
 srcs.append("%s.v" % testbench)
 src = ' '.join(srcs)
 build_cmd = "iverilog -o %s.vvp %s" % (testbench, src)
 def bench():
    # Parameters
    TARGET = "SIM"
    # Inputs
    clk = Signal(bool(0))
    rst = Signal(bool(0))
    current_test = Signal(intbv(0)[8:])
    btnu = Signal(bool(0))
    btnl = Signal(bool(0))
    btnd = Signal(bool(0))
    btnr = Signal(bool(0))
    btnc = Signal(bool(0))
    sw = Signal(intbv(0)[4:])
    phy_rx_clk = Signal(bool(0))
    phy_rxd = Signal(intbv(0)[8:])
    phy_rx_dv = Signal(bool(0))
    phy_rx_er = Signal(bool(0))
    phy_tx_clk = Signal(bool(0))
    phy_int_n = Signal(bool(1))
    uart_rxd = Signal(bool(0))
    uart_cts = Signal(bool(0))
    # Outputs
    led = Signal(intbv(0)[8:])
    phy_gtx_clk = Signal(bool(0))
    phy_txd = Signal(intbv(0)[8:])
    phy_tx_en = Signal(bool(0))
    phy_tx_er = Signal(bool(0))
    phy_reset_n = Signal(bool(0))
    uart_txd = Signal(bool(0))
    uart_rts = Signal(bool(0))
    # sources and sinks
    mii_select = Signal(bool(0))
    gmii_source = gmii_ep.GMIISource()
    gmii_source_logic = gmii_source.create_logic(
        phy_rx_clk,
        rst,
        txd=phy_rxd,
        tx_en=phy_rx_dv,
        tx_er=phy_rx_er,
        mii_select=mii_select,
        name='gmii_source'
    )
    gmii_sink = gmii_ep.GMIISink()
    gmii_sink_logic = gmii_sink.create_logic(
        phy_tx_clk,
        rst,
        rxd=phy_txd,
        rx_dv=phy_tx_en,
        rx_er=phy_tx_er,
        mii_select=mii_select,
        name='gmii_sink'
    )
    # DUT
    if os.system(build_cmd):
        raise Exception("Error running build command")
    dut = Cosimulation(
        "vvp -m myhdl %s.vvp -lxt2" % testbench,
        clk=clk,
        rst=rst,
        current_test=current_test,
        btnu=btnu,
        btnl=btnl,
        btnd=btnd,
        btnr=btnr,
        btnc=btnc,
        sw=sw,
        led=led,
        phy_rx_clk=phy_rx_clk,
        phy_rxd=phy_rxd,
        phy_rx_dv=phy_rx_dv,
        phy_rx_er=phy_rx_er,
        phy_gtx_clk=phy_gtx_clk,
        phy_tx_clk=phy_tx_clk,
        phy_txd=phy_txd,
        phy_tx_en=phy_tx_en,
        phy_tx_er=phy_tx_er,
        phy_reset_n=phy_reset_n,
        phy_int_n=phy_int_n,
        uart_rxd=uart_rxd,
        uart_txd=uart_txd,
        uart_rts=uart_rts,
        uart_cts=uart_cts
    )
    @always(delay(4))
    def clkgen():
        clk.next = not clk
    rx_clk_hp = Signal(int(4))
    @instance
    def rx_clk_gen():
        while True:
            yield delay(int(rx_clk_hp))
            phy_rx_clk.next = not phy_rx_clk
            phy_tx_clk.next = not phy_tx_clk
    @instance
    def check():
        yield delay(100)
        yield clk.posedge
        rst.next = 1
        yield clk.posedge
        rst.next = 0
        yield clk.posedge
        yield delay(100)
        yield clk.posedge
        # testbench stimulus
        yield clk.posedge
        print("test 1: test UDP RX packet")
        current_test.next = 1
        test_frame = udp_ep.UDPFrame()
        test_frame.eth_dest_mac = 0x020000000000
        test_frame.eth_src_mac = 0xDAD1D2D3D4D5
        test_frame.eth_type = 0x0800
        test_frame.ip_version = 4
        test_frame.ip_ihl = 5
        test_frame.ip_dscp = 0
        test_frame.ip_ecn = 0
        test_frame.ip_length = None
        test_frame.ip_identification = 0
        test_frame.ip_flags = 2
        test_frame.ip_fragment_offset = 0
        test_frame.ip_ttl = 64
        test_frame.ip_protocol = 0x11
        test_frame.ip_header_checksum = None
        test_frame.ip_source_ip = 0xc0a80181
        test_frame.ip_dest_ip = 0xc0a80180
        test_frame.udp_source_port = 5678
        test_frame.udp_dest_port = 1234
        test_frame.payload = bytearray(range(32))
        test_frame.build()
        gmii_source.send(b'\x55\x55\x55\x55\x55\x55\x55\xD5'+test_frame.build_eth().build_axis_fcs().data)
        # wait for ARP request packet
        while gmii_sink.empty():
            yield clk.posedge
        rx_frame = gmii_sink.recv()
        check_eth_frame = eth_ep.EthFrame()
        check_eth_frame.parse_axis_fcs(rx_frame.data[8:])
        check_frame = arp_ep.ARPFrame()
        check_frame.parse_eth(check_eth_frame)
        print(check_frame)
        assert check_frame.eth_dest_mac == 0xFFFFFFFFFFFF
        assert check_frame.eth_src_mac == 0x020000000000
        assert check_frame.eth_type == 0x0806
        assert check_frame.arp_htype == 0x0001
        assert check_frame.arp_ptype == 0x0800
        assert check_frame.arp_hlen == 6
        assert check_frame.arp_plen == 4
        assert check_frame.arp_oper == 1
        assert check_frame.arp_sha == 0x020000000000
        assert check_frame.arp_spa == 0xc0a80180
        assert check_frame.arp_tha == 0x000000000000
        assert check_frame.arp_tpa == 0xc0a80181
        # generate response
        arp_frame = arp_ep.ARPFrame()
        arp_frame.eth_dest_mac = 0x020000000000
        arp_frame.eth_src_mac = 0xDAD1D2D3D4D5
        arp_frame.eth_type = 0x0806
        arp_frame.arp_htype = 0x0001
        arp_frame.arp_ptype = 0x0800
        arp_frame.arp_hlen = 6
        arp_frame.arp_plen = 4
        arp_frame.arp_oper = 2
        arp_frame.arp_sha = 0xDAD1D2D3D4D5
        arp_frame.arp_spa = 0xc0a80181
        arp_frame.arp_tha = 0x020000000000
        arp_frame.arp_tpa = 0xc0a80180
        gmii_source.send(b'\x55\x55\x55\x55\x55\x55\x55\xD5'+arp_frame.build_eth().build_axis_fcs().data)
        while gmii_sink.empty():
            yield clk.posedge
        rx_frame = gmii_sink.recv()
        check_eth_frame = eth_ep.EthFrame()
        check_eth_frame.parse_axis_fcs(rx_frame.data[8:])
        check_frame = udp_ep.UDPFrame()
        check_frame.parse_eth(check_eth_frame)
        print(check_frame)
        assert check_frame.eth_dest_mac == 0xDAD1D2D3D4D5
        assert check_frame.eth_src_mac == 0x020000000000
        assert check_frame.eth_type == 0x0800
        assert check_frame.ip_version == 4
        assert check_frame.ip_ihl == 5
        assert check_frame.ip_dscp == 0
        assert check_frame.ip_ecn == 0
        assert check_frame.ip_identification == 0
        assert check_frame.ip_flags == 2
        assert check_frame.ip_fragment_offset == 0
        assert check_frame.ip_ttl == 64
        assert check_frame.ip_protocol == 0x11
        assert check_frame.ip_source_ip == 0xc0a80180
        assert check_frame.ip_dest_ip == 0xc0a80181
        assert check_frame.udp_source_port == 1234
        assert check_frame.udp_dest_port == 5678
        assert check_frame.payload.data == bytearray(range(32))
        assert gmii_source.empty()
        assert gmii_sink.empty()
        yield delay(100)
        raise StopSimulation
    return instances()
 def test_bench():
    sim = Simulation(bench())
    sim.run()
 if __name__ == '__main__':
    print("Running test...")
    test_bench()
--- a/example/KC705/fpga_gmii/tb/test_fpga_core.v
+++ b/example/KC705/fpga_gmii/tb/test_fpga_core.v
@ -0,0 +1,134 @@
 /*
 Copyright (c) 2015-2018 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
 `timescale 1ns / 1ps
 /*
 * Testbench for fpga_core
 */
 module test_fpga_core;
 // Parameters
 parameter TARGET = "SIM";
 // Inputs
 reg clk = 0;
 reg rst = 0;
 reg [7:0] current_test = 0;
 reg btnu = 0;
 reg btnl = 0;
 reg btnd = 0;
 reg btnr = 0;
 reg btnc = 0;
 reg [3:0] sw = 0;
 reg phy_rx_clk = 0;
 reg [7:0] phy_rxd = 0;
 reg phy_rx_dv = 0;
 reg phy_rx_er = 0;
 reg phy_tx_clk = 0;
 reg phy_int_n = 1;
 reg uart_rxd = 0;
 reg uart_cts = 0;
 // Outputs
 wire [7:0] led;
 wire phy_gtx_clk;
 wire [7:0] phy_txd;
 wire phy_tx_en;
 wire phy_tx_er;
 wire phy_reset_n;
 wire uart_txd;
 wire uart_rts;
 initial begin
    // myhdl integration
    $from_myhdl(
        clk,
        rst,
        current_test,
        btnu,
        btnl,
        btnd,
        btnr,
        btnc,
        sw,
        phy_rx_clk,
        phy_rxd,
        phy_rx_dv,
        phy_rx_er,
        phy_tx_clk,
        phy_int_n,
        uart_rxd,
        uart_cts
    );
    $to_myhdl(
        led,
        phy_gtx_clk,
        phy_txd,
        phy_tx_en,
        phy_tx_er,
        phy_reset_n,
        uart_txd,
        uart_rts
    );
    // dump file
    $dumpfile("test_fpga_core.lxt");
    $dumpvars(0, test_fpga_core);
 end
 fpga_core #(
    .TARGET(TARGET)
 )
 UUT (
    .clk(clk),
    .rst(rst),
    .btnu(btnu),
    .btnl(btnl),
    .btnd(btnd),
    .btnr(btnr),
    .btnc(btnc),
    .sw(sw),
    .led(led),
    .phy_rx_clk(phy_rx_clk),
    .phy_rxd(phy_rxd),
    .phy_rx_dv(phy_rx_dv),
    .phy_rx_er(phy_rx_er),
    .phy_gtx_clk(phy_gtx_clk),
    .phy_tx_clk(phy_tx_clk),
    .phy_txd(phy_txd),
    .phy_tx_en(phy_tx_en),
    .phy_tx_er(phy_tx_er),
    .phy_reset_n(phy_reset_n),
    .phy_int_n(phy_int_n),
    .uart_rxd(uart_rxd),
    .uart_txd(uart_txd),
    .uart_rts(uart_rts),
    .uart_cts(uart_cts)
 );
 endmodule
--- a/example/KC705/fpga_gmii/tb/udp_ep.py
+++ b/example/KC705/fpga_gmii/tb/udp_ep.py
@ -0,0 +1 @@
 ../lib/eth/tb/udp_ep.py