#!/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 axis_ep import eth_ep import rgmii_ep module = 'eth_mac_1g_rgmii_fifo' testbench = 'test_%s' % module srcs = [] srcs.append("../rtl/%s.v" % module) srcs.append("../rtl/lfsr.v") srcs.append("../rtl/axis_gmii_rx.v") srcs.append("../rtl/axis_gmii_tx.v") srcs.append("../rtl/eth_mac_1g.v") srcs.append("../rtl/eth_mac_1g_rgmii.v") srcs.append("../rtl/rgmii_phy_if.v") srcs.append("../rtl/iddr.v") srcs.append("../rtl/oddr.v") srcs.append("../rtl/ssio_ddr_in.v") srcs.append("../rtl/ssio_ddr_out.v") srcs.append("../lib/axis/rtl/axis_async_fifo.v") srcs.append("../lib/axis/rtl/axis_async_fifo_adapter.v") srcs.append("%s.v" % testbench) src = ' '.join(srcs) build_cmd = "iverilog -o %s.vvp %s" % (testbench, src) def bench(): # Parameters TARGET = "SIM" IODDR_STYLE = "IODDR2" CLOCK_INPUT_STYLE = "BUFIO2" USE_CLK90 = "TRUE" AXIS_DATA_WIDTH = 8 AXIS_KEEP_ENABLE = (AXIS_DATA_WIDTH>8) AXIS_KEEP_WIDTH = (AXIS_DATA_WIDTH/8) ENABLE_PADDING = 1 MIN_FRAME_LENGTH = 64 TX_FIFO_DEPTH = 4096 TX_FIFO_PIPELINE_OUTPUT = 2 TX_FRAME_FIFO = 1 TX_DROP_BAD_FRAME = TX_FRAME_FIFO TX_DROP_WHEN_FULL = 0 RX_FIFO_DEPTH = 4096 RX_FIFO_PIPELINE_OUTPUT = 2 RX_FRAME_FIFO = 1 RX_DROP_BAD_FRAME = RX_FRAME_FIFO RX_DROP_WHEN_FULL = RX_FRAME_FIFO # Inputs clk = Signal(bool(0)) rst = Signal(bool(0)) current_test = Signal(intbv(0)[8:]) gtx_clk = Signal(bool(0)) gtx_clk90 = Signal(bool(0)) gtx_rst = Signal(bool(0)) logic_clk = Signal(bool(0)) logic_rst = Signal(bool(0)) tx_axis_tdata = Signal(intbv(0)[AXIS_DATA_WIDTH:]) tx_axis_tkeep = Signal(intbv(1)[AXIS_KEEP_WIDTH:]) tx_axis_tvalid = Signal(bool(0)) tx_axis_tlast = Signal(bool(0)) tx_axis_tuser = Signal(bool(0)) rx_axis_tready = Signal(bool(0)) rgmii_rx_clk = Signal(bool(0)) rgmii_rxd = Signal(intbv(0)[4:]) rgmii_rx_ctl = Signal(bool(0)) ifg_delay = Signal(intbv(0)[8:]) # Outputs tx_axis_tready = Signal(bool(0)) rx_axis_tdata = Signal(intbv(0)[AXIS_DATA_WIDTH:]) rx_axis_tkeep = Signal(intbv(1)[AXIS_KEEP_WIDTH:]) rx_axis_tvalid = Signal(bool(0)) rx_axis_tlast = Signal(bool(0)) rx_axis_tuser = Signal(bool(0)) rgmii_tx_clk = Signal(bool(0)) rgmii_txd = Signal(intbv(0)[4:]) rgmii_tx_ctl = Signal(bool(0)) tx_error_underflow = Signal(bool(0)) tx_fifo_overflow = Signal(bool(0)) tx_fifo_bad_frame = Signal(bool(0)) tx_fifo_good_frame = Signal(bool(0)) rx_error_bad_frame = Signal(bool(0)) rx_error_bad_fcs = Signal(bool(0)) rx_fifo_overflow = Signal(bool(0)) rx_fifo_bad_frame = Signal(bool(0)) rx_fifo_good_frame = Signal(bool(0)) speed = Signal(intbv(0)[2:]) # sources and sinks axis_source_pause = Signal(bool(0)) axis_sink_pause = Signal(bool(0)) mii_select = Signal(bool(0)) rgmii_source = rgmii_ep.RGMIISource() rgmii_source_logic = rgmii_source.create_logic( rgmii_rx_clk, rst, txd=rgmii_rxd, tx_ctl=rgmii_rx_ctl, mii_select=mii_select, name='rgmii_source' ) rgmii_sink = rgmii_ep.RGMIISink() rgmii_sink_logic = rgmii_sink.create_logic( rgmii_tx_clk, rst, rxd=rgmii_txd, rx_ctl=rgmii_tx_ctl, mii_select=mii_select, name='rgmii_sink' ) axis_source = axis_ep.AXIStreamSource() axis_source_logic = axis_source.create_logic( logic_clk, logic_rst, tdata=tx_axis_tdata, tkeep=tx_axis_tkeep, tvalid=tx_axis_tvalid, tready=tx_axis_tready, tlast=tx_axis_tlast, tuser=tx_axis_tuser, pause=axis_source_pause, name='axis_source' ) axis_sink = axis_ep.AXIStreamSink() axis_sink_logic = axis_sink.create_logic( logic_clk, logic_rst, tdata=rx_axis_tdata, tkeep=rx_axis_tkeep, tvalid=rx_axis_tvalid, tready=rx_axis_tready, tlast=rx_axis_tlast, tuser=rx_axis_tuser, pause=axis_sink_pause, name='axis_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, gtx_clk=gtx_clk, gtx_clk90=gtx_clk90, gtx_rst=gtx_rst, logic_clk=logic_clk, logic_rst=logic_rst, tx_axis_tdata=tx_axis_tdata, tx_axis_tkeep=tx_axis_tkeep, 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_tkeep=rx_axis_tkeep, rx_axis_tvalid=rx_axis_tvalid, rx_axis_tready=rx_axis_tready, rx_axis_tlast=rx_axis_tlast, rx_axis_tuser=rx_axis_tuser, rgmii_rx_clk=rgmii_rx_clk, rgmii_rxd=rgmii_rxd, rgmii_rx_ctl=rgmii_rx_ctl, rgmii_tx_clk=rgmii_tx_clk, rgmii_txd=rgmii_txd, rgmii_tx_ctl=rgmii_tx_ctl, tx_error_underflow=tx_error_underflow, tx_fifo_overflow=tx_fifo_overflow, tx_fifo_bad_frame=tx_fifo_bad_frame, tx_fifo_good_frame=tx_fifo_good_frame, rx_error_bad_frame=rx_error_bad_frame, rx_error_bad_fcs=rx_error_bad_fcs, rx_fifo_overflow=rx_fifo_overflow, rx_fifo_bad_frame=rx_fifo_bad_frame, rx_fifo_good_frame=rx_fifo_good_frame, speed=speed, ifg_delay=ifg_delay ) @always(delay(4)) def clkgen(): clk.next = not clk gtx_clk.next = not clk logic_clk.next = not clk @instance def clkgen2(): yield delay(4+2) while True: gtx_clk90.next = not gtx_clk90 yield delay(4) rx_clk_hp = Signal(int(4)) @instance def rx_clk_gen(): while True: yield delay(int(rx_clk_hp)) rgmii_rx_clk.next = not rgmii_rx_clk rx_error_bad_frame_asserted = Signal(bool(0)) rx_error_bad_fcs_asserted = Signal(bool(0)) @always(clk.posedge) def monitor(): if (rx_error_bad_frame): rx_error_bad_frame_asserted.next = 1 if (rx_error_bad_fcs): rx_error_bad_fcs_asserted.next = 1 @instance def check(): yield delay(100) yield clk.posedge rst.next = 1 gtx_rst.next = 1 logic_rst.next = 1 yield clk.posedge rst.next = 0 gtx_rst.next = 0 logic_rst.next = 0 yield clk.posedge yield delay(100) yield clk.posedge ifg_delay.next = 12 # testbench stimulus for rate, mii in [(4, 0), (20, 1), (200, 1)]: rx_clk_hp.next = rate mii_select.next = mii yield delay(1000) yield clk.posedge print("test 1: test rx packet") current_test.next = 1 test_frame = eth_ep.EthFrame() test_frame.eth_dest_mac = 0xDAD1D2D3D4D5 test_frame.eth_src_mac = 0x5A5152535455 test_frame.eth_type = 0x8000 test_frame.payload = bytearray(range(32)) test_frame.update_fcs() axis_frame = test_frame.build_axis_fcs() rgmii_source.send(b'\x55\x55\x55\x55\x55\x55\x55\xD5'+bytearray(axis_frame)) yield axis_sink.wait() rx_frame = axis_sink.recv() eth_frame = eth_ep.EthFrame() eth_frame.parse_axis(rx_frame) eth_frame.update_fcs() assert eth_frame == test_frame yield delay(100) yield clk.posedge print("test 2: test tx packet") current_test.next = 2 test_frame = eth_ep.EthFrame() test_frame.eth_dest_mac = 0xDAD1D2D3D4D5 test_frame.eth_src_mac = 0x5A5152535455 test_frame.eth_type = 0x8000 test_frame.payload = bytearray(range(32)) test_frame.update_fcs() axis_frame = test_frame.build_axis() axis_source.send(axis_frame) yield rgmii_sink.wait() rx_frame = rgmii_sink.recv() assert rx_frame.data[0:8] == bytearray(b'\x55\x55\x55\x55\x55\x55\x55\xD5') eth_frame = eth_ep.EthFrame() eth_frame.parse_axis_fcs(rx_frame.data[8:]) print(hex(eth_frame.eth_fcs)) print(hex(eth_frame.calc_fcs())) assert len(eth_frame.payload.data) == 46 assert eth_frame.eth_fcs == eth_frame.calc_fcs() assert eth_frame.eth_dest_mac == test_frame.eth_dest_mac assert eth_frame.eth_src_mac == test_frame.eth_src_mac assert eth_frame.eth_type == test_frame.eth_type assert eth_frame.payload.data.index(test_frame.payload.data) == 0 yield delay(100) raise StopSimulation return instances() def test_bench(): sim = Simulation(bench()) sim.run() if __name__ == '__main__': print("Running test...") test_bench()