pluto_hdl_adi/projects/adrv9371x/zcu102/system_top.v

244 lines
7.8 KiB
Verilog

// ***************************************************************************
// ***************************************************************************
// Copyright (C) 2017-2023 Analog Devices, Inc. All rights reserved.
//
// In this HDL repository, there are many different and unique modules, consisting
// of various HDL (Verilog or VHDL) components. The individual modules are
// developed independently, and may be accompanied by separate and unique license
// terms.
//
// The user should read each of these license terms, and understand the
// freedoms and responsibilities that he or she has by using this source/core.
//
// This core 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.
//
// Redistribution and use of source or resulting binaries, with or without modification
// of this file, are permitted under one of the following two license terms:
//
// 1. The GNU General Public License version 2 as published by the
// Free Software Foundation, which can be found in the top level directory
// of this repository (LICENSE_GPL2), and also online at:
// <https://www.gnu.org/licenses/old-licenses/gpl-2.0.html>
//
// OR
//
// 2. An ADI specific BSD license, which can be found in the top level directory
// of this repository (LICENSE_ADIBSD), and also on-line at:
// https://github.com/analogdevicesinc/hdl/blob/master/LICENSE_ADIBSD
// This will allow to generate bit files and not release the source code,
// as long as it attaches to an ADI device.
//
// ***************************************************************************
// ***************************************************************************
`timescale 1ns/100ps
module system_top (
input [12:0] gpio_bd_i,
output [ 7:0] gpio_bd_o,
inout iic_scl,
inout iic_sda,
input ref_clk0_p,
input ref_clk0_n,
input ref_clk1_p,
input ref_clk1_n,
input [ 3:0] rx_data_p,
input [ 3:0] rx_data_n,
output [ 3:0] tx_data_p,
output [ 3:0] tx_data_n,
output rx_sync_p,
output rx_sync_n,
output rx_os_sync_p,
output rx_os_sync_n,
input tx_sync_p,
input tx_sync_n,
input sysref_p,
input sysref_n,
output spi_csn_ad9528,
output spi_csn_ad9371,
output spi_clk,
output spi_mosi,
input spi_miso,
inout ad9528_reset_b,
inout ad9528_sysref_req,
inout ad9371_tx1_enable,
inout ad9371_tx2_enable,
inout ad9371_rx1_enable,
inout ad9371_rx2_enable,
inout ad9371_test,
inout ad9371_reset_b,
inout ad9371_gpint,
inout ad9371_gpio_00,
inout ad9371_gpio_01,
inout ad9371_gpio_02,
inout ad9371_gpio_03,
inout ad9371_gpio_04,
inout ad9371_gpio_05,
inout ad9371_gpio_06,
inout ad9371_gpio_07,
inout ad9371_gpio_15,
inout ad9371_gpio_08,
inout ad9371_gpio_09,
inout ad9371_gpio_10,
inout ad9371_gpio_11,
inout ad9371_gpio_12,
inout ad9371_gpio_14,
inout ad9371_gpio_13,
inout ad9371_gpio_17,
inout ad9371_gpio_16,
inout ad9371_gpio_18
);
// internal signals
wire [94:0] gpio_i;
wire [94:0] gpio_o;
wire [94:0] gpio_t;
wire [20:0] gpio_bd;
wire [ 2:0] spi_csn;
wire ref_clk0;
wire ref_clk1;
wire rx_sync;
wire rx_os_sync;
wire tx_sync;
wire sysref;
// instantiations
IBUFDS_GTE4 i_ibufds_rx_ref_clk (
.CEB (1'd0),
.I (ref_clk0_p),
.IB (ref_clk0_n),
.O (ref_clk0),
.ODIV2 ());
IBUFDS_GTE4 #(
.REFCLK_HROW_CK_SEL(2'b00) // ODIV2 = O
) i_ibufds_ref_clk1 (
.CEB (1'd0),
.I (ref_clk1_p),
.IB (ref_clk1_n),
.O (ref_clk1),
.ODIV2 (ref_clk1_odiv2));
BUFG_GT i_bufg_ref_clk (
.I (ref_clk1_odiv2),
.O (ref_clk1_bufg));
OBUFDS i_obufds_rx_sync (
.I (rx_sync),
.O (rx_sync_p),
.OB (rx_sync_n));
OBUFDS i_obufds_rx_os_sync (
.I (rx_os_sync),
.O (rx_os_sync_p),
.OB (rx_os_sync_n));
IBUFDS i_ibufds_tx_sync (
.I (tx_sync_p),
.IB (tx_sync_n),
.O (tx_sync));
IBUFDS i_ibufds_sysref (
.I (sysref_p),
.IB (sysref_n),
.O (sysref));
ad_iobuf #(
.DATA_WIDTH(28)
) i_iobuf (
.dio_t ({gpio_t[59:32]}),
.dio_i ({gpio_o[59:32]}),
.dio_o ({gpio_i[59:32]}),
.dio_p ({ ad9528_reset_b, // 59
ad9528_sysref_req, // 58
ad9371_tx1_enable, // 57
ad9371_tx2_enable, // 56
ad9371_rx1_enable, // 55
ad9371_rx2_enable, // 54
ad9371_test, // 53
ad9371_reset_b, // 52
ad9371_gpint, // 51
ad9371_gpio_00, // 50
ad9371_gpio_01, // 49
ad9371_gpio_02, // 48
ad9371_gpio_03, // 47
ad9371_gpio_04, // 46
ad9371_gpio_05, // 45
ad9371_gpio_06, // 44
ad9371_gpio_07, // 43
ad9371_gpio_15, // 42
ad9371_gpio_08, // 41
ad9371_gpio_09, // 40
ad9371_gpio_10, // 39
ad9371_gpio_11, // 38
ad9371_gpio_12, // 37
ad9371_gpio_14, // 36
ad9371_gpio_13, // 35
ad9371_gpio_17, // 34
ad9371_gpio_16, // 33
ad9371_gpio_18})); // 32
assign gpio_i[ 7: 0] = gpio_o[ 7: 0];
assign gpio_i[20: 8] = gpio_bd_i;
assign gpio_i[31:21] = gpio_o[31:21];
assign gpio_i[94:60] = gpio_o[94:60];
assign gpio_bd_o = gpio_o[ 7: 0];
assign spi_csn_ad9528 = spi_csn[0];
assign spi_csn_ad9371 = spi_csn[1];
system_wrapper i_system_wrapper (
.dac_fifo_bypass (gpio_o[60]),
.adc_fir_filter_active (gpio_o[61]),
.dac_fir_filter_active (gpio_o[62]),
.gpio_i (gpio_i),
.gpio_o (gpio_o),
.gpio_t (gpio_t),
.rx_data_0_n (rx_data_n[0]),
.rx_data_0_p (rx_data_p[0]),
.rx_data_1_n (rx_data_n[1]),
.rx_data_1_p (rx_data_p[1]),
.rx_data_2_n (rx_data_n[2]),
.rx_data_2_p (rx_data_p[2]),
.rx_data_3_n (rx_data_n[3]),
.rx_data_3_p (rx_data_p[3]),
.rx_ref_clk_0 (ref_clk1),
.rx_ref_clk_2 (ref_clk1),
.rx_sync_0 (rx_sync),
.rx_sync_2 (rx_os_sync),
.rx_sysref_0 (sysref),
.rx_sysref_2 (sysref),
.spi0_sclk (spi_clk),
.spi0_csn (spi_csn),
.spi0_miso (spi_miso),
.spi0_mosi (spi_mosi),
.spi1_sclk (),
.spi1_csn (),
.spi1_miso (1'b0),
.spi1_mosi (),
.tx_data_0_n (tx_data_n[0]),
.tx_data_0_p (tx_data_p[0]),
.tx_data_1_n (tx_data_n[1]),
.tx_data_1_p (tx_data_p[1]),
.tx_data_2_n (tx_data_n[2]),
.tx_data_2_p (tx_data_p[2]),
.tx_data_3_n (tx_data_n[3]),
.tx_data_3_p (tx_data_p[3]),
.tx_ref_clk_0 (ref_clk1),
.tx_sync_0 (tx_sync),
.tx_sysref_0 (sysref),
.ref_clk (ref_clk1_bufg));
endmodule