// *************************************************************************** // *************************************************************************** // Copyright (C) 2014-2023 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: // // // 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. // // *************************************************************************** // *************************************************************************** // AUTO GENERATED BY avl_adxphy.pl, DO NOT MODIFY! `timescale 1ns/1ps module avl_adxphy #( // parameters parameter integer NUM_OF_LANES = 4 ) ( // rx-ip interface output [((NUM_OF_LANES* 1)-1):0] rx_ip_locked, output [((NUM_OF_LANES* 1)-1):0] rx_ip_cal_busy, output [((NUM_OF_LANES* 1)-1):0] rx_ip_valid, output [((NUM_OF_LANES*32)-1):0] rx_ip_data, output [((NUM_OF_LANES* 4)-1):0] rx_ip_disperr, output [((NUM_OF_LANES* 4)-1):0] rx_ip_deterr, output [((NUM_OF_LANES* 4)-1):0] rx_ip_kchar, output [((NUM_OF_LANES* 1)-1):0] rx_ip_full, output [((NUM_OF_LANES* 1)-1):0] rx_ip_empty, input [((NUM_OF_LANES* 1)-1):0] rx_ip_align_en, input [((NUM_OF_LANES* 1)-1):0] rx_ip_lane_polarity, input [((NUM_OF_LANES* 1)-1):0] rx_ip_lane_powerdown, input rx_ip_bit_reversal, input rx_ip_byte_reversal, // rx-phy interface(s) input rx_phy_locked_0, input rx_phy_cal_busy_0, input rx_phy_valid_0, input [31:0] rx_phy_data_0, input [ 3:0] rx_phy_disperr_0, input [ 3:0] rx_phy_deterr_0, input [ 3:0] rx_phy_kchar_0, input rx_phy_full_0, input rx_phy_empty_0, output rx_phy_align_en_0, output rx_phy_lane_polarity_0, output rx_phy_lane_powerdown_0, output rx_phy_bit_reversal_0, output rx_phy_byte_reversal_0, output rx_phy_analogreset_0, output rx_phy_digitalreset_0, input rx_phy_locked_1, input rx_phy_cal_busy_1, input rx_phy_valid_1, input [31:0] rx_phy_data_1, input [ 3:0] rx_phy_disperr_1, input [ 3:0] rx_phy_deterr_1, input [ 3:0] rx_phy_kchar_1, input rx_phy_full_1, input rx_phy_empty_1, output rx_phy_align_en_1, output rx_phy_lane_polarity_1, output rx_phy_lane_powerdown_1, output rx_phy_bit_reversal_1, output rx_phy_byte_reversal_1, output rx_phy_analogreset_1, output rx_phy_digitalreset_1, input rx_phy_locked_2, input rx_phy_cal_busy_2, input rx_phy_valid_2, input [31:0] rx_phy_data_2, input [ 3:0] rx_phy_disperr_2, input [ 3:0] rx_phy_deterr_2, input [ 3:0] rx_phy_kchar_2, input rx_phy_full_2, input rx_phy_empty_2, output rx_phy_align_en_2, output rx_phy_lane_polarity_2, output rx_phy_lane_powerdown_2, output rx_phy_bit_reversal_2, output rx_phy_byte_reversal_2, output rx_phy_analogreset_2, output rx_phy_digitalreset_2, input rx_phy_locked_3, input rx_phy_cal_busy_3, input rx_phy_valid_3, input [31:0] rx_phy_data_3, input [ 3:0] rx_phy_disperr_3, input [ 3:0] rx_phy_deterr_3, input [ 3:0] rx_phy_kchar_3, input rx_phy_full_3, input rx_phy_empty_3, output rx_phy_align_en_3, output rx_phy_lane_polarity_3, output rx_phy_lane_powerdown_3, output rx_phy_bit_reversal_3, output rx_phy_byte_reversal_3, output rx_phy_analogreset_3, output rx_phy_digitalreset_3, input rx_phy_locked_4, input rx_phy_cal_busy_4, input rx_phy_valid_4, input [31:0] rx_phy_data_4, input [ 3:0] rx_phy_disperr_4, input [ 3:0] rx_phy_deterr_4, input [ 3:0] rx_phy_kchar_4, input rx_phy_full_4, input rx_phy_empty_4, output rx_phy_align_en_4, output rx_phy_lane_polarity_4, output rx_phy_lane_powerdown_4, output rx_phy_bit_reversal_4, output rx_phy_byte_reversal_4, output rx_phy_analogreset_4, output rx_phy_digitalreset_4, input rx_phy_locked_5, input rx_phy_cal_busy_5, input rx_phy_valid_5, input [31:0] rx_phy_data_5, input [ 3:0] rx_phy_disperr_5, input [ 3:0] rx_phy_deterr_5, input [ 3:0] rx_phy_kchar_5, input rx_phy_full_5, input rx_phy_empty_5, output rx_phy_align_en_5, output rx_phy_lane_polarity_5, output rx_phy_lane_powerdown_5, output rx_phy_bit_reversal_5, output rx_phy_byte_reversal_5, output rx_phy_analogreset_5, output rx_phy_digitalreset_5, input rx_phy_locked_6, input rx_phy_cal_busy_6, input rx_phy_valid_6, input [31:0] rx_phy_data_6, input [ 3:0] rx_phy_disperr_6, input [ 3:0] rx_phy_deterr_6, input [ 3:0] rx_phy_kchar_6, input rx_phy_full_6, input rx_phy_empty_6, output rx_phy_align_en_6, output rx_phy_lane_polarity_6, output rx_phy_lane_powerdown_6, output rx_phy_bit_reversal_6, output rx_phy_byte_reversal_6, output rx_phy_analogreset_6, output rx_phy_digitalreset_6, input rx_phy_locked_7, input rx_phy_cal_busy_7, input rx_phy_valid_7, input [31:0] rx_phy_data_7, input [ 3:0] rx_phy_disperr_7, input [ 3:0] rx_phy_deterr_7, input [ 3:0] rx_phy_kchar_7, input rx_phy_full_7, input rx_phy_empty_7, output rx_phy_align_en_7, output rx_phy_lane_polarity_7, output rx_phy_lane_powerdown_7, output rx_phy_bit_reversal_7, output rx_phy_byte_reversal_7, output rx_phy_analogreset_7, output rx_phy_digitalreset_7, // rx-core interface input [((NUM_OF_LANES* 1)-1):0] rx_core_analogreset, input [((NUM_OF_LANES* 1)-1):0] rx_core_digitalreset, output [((NUM_OF_LANES* 1)-1):0] rx_core_locked, output [((NUM_OF_LANES* 1)-1):0] rx_core_cal_busy, // tx-ip interface output [((NUM_OF_LANES* 1)-1):0] tx_ip_cal_busy, output [((NUM_OF_LANES* 1)-1):0] tx_ip_full, output [((NUM_OF_LANES* 1)-1):0] tx_ip_empty, input [((NUM_OF_LANES*32)-1):0] tx_ip_data, input [((NUM_OF_LANES* 4)-1):0] tx_ip_kchar, input [((NUM_OF_LANES* 1)-1):0] tx_ip_elecidle, input [((NUM_OF_LANES* 1)-1):0] tx_ip_lane_polarity, input [((NUM_OF_LANES* 1)-1):0] tx_ip_lane_powerdown, input tx_ip_bit_reversal, input tx_ip_byte_reversal, // tx-phy interface input tx_phy_cal_busy_0, input tx_phy_full_0, input tx_phy_empty_0, output [31:0] tx_phy_data_0, output [ 3:0] tx_phy_kchar_0, output tx_phy_elecidle_0, output tx_phy_lane_polarity_0, output tx_phy_lane_powerdown_0, output tx_phy_bit_reversal_0, output tx_phy_byte_reversal_0, output tx_phy_analogreset_0, output tx_phy_digitalreset_0, input tx_phy_cal_busy_1, input tx_phy_full_1, input tx_phy_empty_1, output [31:0] tx_phy_data_1, output [ 3:0] tx_phy_kchar_1, output tx_phy_elecidle_1, output tx_phy_lane_polarity_1, output tx_phy_lane_powerdown_1, output tx_phy_bit_reversal_1, output tx_phy_byte_reversal_1, output tx_phy_analogreset_1, output tx_phy_digitalreset_1, input tx_phy_cal_busy_2, input tx_phy_full_2, input tx_phy_empty_2, output [31:0] tx_phy_data_2, output [ 3:0] tx_phy_kchar_2, output tx_phy_elecidle_2, output tx_phy_lane_polarity_2, output tx_phy_lane_powerdown_2, output tx_phy_bit_reversal_2, output tx_phy_byte_reversal_2, output tx_phy_analogreset_2, output tx_phy_digitalreset_2, input tx_phy_cal_busy_3, input tx_phy_full_3, input tx_phy_empty_3, output [31:0] tx_phy_data_3, output [ 3:0] tx_phy_kchar_3, output tx_phy_elecidle_3, output tx_phy_lane_polarity_3, output tx_phy_lane_powerdown_3, output tx_phy_bit_reversal_3, output tx_phy_byte_reversal_3, output tx_phy_analogreset_3, output tx_phy_digitalreset_3, input tx_phy_cal_busy_4, input tx_phy_full_4, input tx_phy_empty_4, output [31:0] tx_phy_data_4, output [ 3:0] tx_phy_kchar_4, output tx_phy_elecidle_4, output tx_phy_lane_polarity_4, output tx_phy_lane_powerdown_4, output tx_phy_bit_reversal_4, output tx_phy_byte_reversal_4, output tx_phy_analogreset_4, output tx_phy_digitalreset_4, input tx_phy_cal_busy_5, input tx_phy_full_5, input tx_phy_empty_5, output [31:0] tx_phy_data_5, output [ 3:0] tx_phy_kchar_5, output tx_phy_elecidle_5, output tx_phy_lane_polarity_5, output tx_phy_lane_powerdown_5, output tx_phy_bit_reversal_5, output tx_phy_byte_reversal_5, output tx_phy_analogreset_5, output tx_phy_digitalreset_5, input tx_phy_cal_busy_6, input tx_phy_full_6, input tx_phy_empty_6, output [31:0] tx_phy_data_6, output [ 3:0] tx_phy_kchar_6, output tx_phy_elecidle_6, output tx_phy_lane_polarity_6, output tx_phy_lane_powerdown_6, output tx_phy_bit_reversal_6, output tx_phy_byte_reversal_6, output tx_phy_analogreset_6, output tx_phy_digitalreset_6, input tx_phy_cal_busy_7, input tx_phy_full_7, input tx_phy_empty_7, output [31:0] tx_phy_data_7, output [ 3:0] tx_phy_kchar_7, output tx_phy_elecidle_7, output tx_phy_lane_polarity_7, output tx_phy_lane_powerdown_7, output tx_phy_bit_reversal_7, output tx_phy_byte_reversal_7, output tx_phy_analogreset_7, output tx_phy_digitalreset_7, // tx-core interface input [((NUM_OF_LANES* 1)-1):0] tx_core_analogreset, input [((NUM_OF_LANES* 1)-1):0] tx_core_digitalreset, output [((NUM_OF_LANES* 1)-1):0] tx_core_cal_busy ); // rx assignments generate if (NUM_OF_LANES > 0) begin assign rx_core_locked[0] = rx_phy_locked_0; assign rx_core_cal_busy[0] = rx_phy_cal_busy_0; assign rx_ip_locked[0] = rx_phy_locked_0; assign rx_ip_cal_busy[0] = rx_phy_cal_busy_0; assign rx_ip_valid[0] = rx_phy_valid_0; assign rx_ip_data[((32*1)-1):(32*0)] = rx_phy_data_0; assign rx_ip_disperr[((4*1)-1):(4*0)] = rx_phy_disperr_0; assign rx_ip_deterr[((4*1)-1):(4*0)] = rx_phy_deterr_0; assign rx_ip_kchar[((4*1)-1):(4*0)] = rx_phy_kchar_0; assign rx_ip_full[0] = rx_phy_full_0; assign rx_ip_empty[0] = rx_phy_empty_0; end endgenerate generate if (NUM_OF_LANES > 0) begin assign rx_phy_align_en_0 = rx_ip_align_en[0]; assign rx_phy_lane_polarity_0 = rx_ip_lane_polarity[0]; assign rx_phy_lane_powerdown_0 = rx_ip_lane_powerdown[0]; assign rx_phy_analogreset_0 = rx_core_analogreset[0]; assign rx_phy_digitalreset_0 = rx_core_digitalreset[0]; end else begin assign rx_phy_align_en_0 = 1'd0; assign rx_phy_lane_polarity_0 = 1'd0; assign rx_phy_lane_powerdown_0 = 1'd0; assign rx_phy_analogreset_0 = 1'd1; assign rx_phy_digitalreset_0 = 1'd1; end endgenerate assign rx_phy_bit_reversal_0 = rx_ip_bit_reversal; assign rx_phy_byte_reversal_0 = rx_ip_byte_reversal; generate if (NUM_OF_LANES > 1) begin assign rx_core_locked[1] = rx_phy_locked_1; assign rx_core_cal_busy[1] = rx_phy_cal_busy_1; assign rx_ip_locked[1] = rx_phy_locked_1; assign rx_ip_cal_busy[1] = rx_phy_cal_busy_1; assign rx_ip_valid[1] = rx_phy_valid_1; assign rx_ip_data[((32*2)-1):(32*1)] = rx_phy_data_1; assign rx_ip_disperr[((4*2)-1):(4*1)] = rx_phy_disperr_1; assign rx_ip_deterr[((4*2)-1):(4*1)] = rx_phy_deterr_1; assign rx_ip_kchar[((4*2)-1):(4*1)] = rx_phy_kchar_1; assign rx_ip_full[1] = rx_phy_full_1; assign rx_ip_empty[1] = rx_phy_empty_1; end endgenerate generate if (NUM_OF_LANES > 1) begin assign rx_phy_align_en_1 = rx_ip_align_en[1]; assign rx_phy_lane_polarity_1 = rx_ip_lane_polarity[1]; assign rx_phy_lane_powerdown_1 = rx_ip_lane_powerdown[1]; assign rx_phy_analogreset_1 = rx_core_analogreset[1]; assign rx_phy_digitalreset_1 = rx_core_digitalreset[1]; end else begin assign rx_phy_align_en_1 = 1'd0; assign rx_phy_lane_polarity_1 = 1'd0; assign rx_phy_lane_powerdown_1 = 1'd0; assign rx_phy_analogreset_1 = 1'd1; assign rx_phy_digitalreset_1 = 1'd1; end endgenerate assign rx_phy_bit_reversal_1 = rx_ip_bit_reversal; assign rx_phy_byte_reversal_1 = rx_ip_byte_reversal; generate if (NUM_OF_LANES > 2) begin assign rx_core_locked[2] = rx_phy_locked_2; assign rx_core_cal_busy[2] = rx_phy_cal_busy_2; assign rx_ip_locked[2] = rx_phy_locked_2; assign rx_ip_cal_busy[2] = rx_phy_cal_busy_2; assign rx_ip_valid[2] = rx_phy_valid_2; assign rx_ip_data[((32*3)-1):(32*2)] = rx_phy_data_2; assign rx_ip_disperr[((4*3)-1):(4*2)] = rx_phy_disperr_2; assign rx_ip_deterr[((4*3)-1):(4*2)] = rx_phy_deterr_2; assign rx_ip_kchar[((4*3)-1):(4*2)] = rx_phy_kchar_2; assign rx_ip_full[2] = rx_phy_full_2; assign rx_ip_empty[2] = rx_phy_empty_2; end endgenerate generate if (NUM_OF_LANES > 2) begin assign rx_phy_align_en_2 = rx_ip_align_en[2]; assign rx_phy_lane_polarity_2 = rx_ip_lane_polarity[2]; assign rx_phy_lane_powerdown_2 = rx_ip_lane_powerdown[2]; assign rx_phy_analogreset_2 = rx_core_analogreset[2]; assign rx_phy_digitalreset_2 = rx_core_digitalreset[2]; end else begin assign rx_phy_align_en_2 = 1'd0; assign rx_phy_lane_polarity_2 = 1'd0; assign rx_phy_lane_powerdown_2 = 1'd0; assign rx_phy_analogreset_2 = 1'd1; assign rx_phy_digitalreset_2 = 1'd1; end endgenerate assign rx_phy_bit_reversal_2 = rx_ip_bit_reversal; assign rx_phy_byte_reversal_2 = rx_ip_byte_reversal; generate if (NUM_OF_LANES > 3) begin assign rx_core_locked[3] = rx_phy_locked_3; assign rx_core_cal_busy[3] = rx_phy_cal_busy_3; assign rx_ip_locked[3] = rx_phy_locked_3; assign rx_ip_cal_busy[3] = rx_phy_cal_busy_3; assign rx_ip_valid[3] = rx_phy_valid_3; assign rx_ip_data[((32*4)-1):(32*3)] = rx_phy_data_3; assign rx_ip_disperr[((4*4)-1):(4*3)] = rx_phy_disperr_3; assign rx_ip_deterr[((4*4)-1):(4*3)] = rx_phy_deterr_3; assign rx_ip_kchar[((4*4)-1):(4*3)] = rx_phy_kchar_3; assign rx_ip_full[3] = rx_phy_full_3; assign rx_ip_empty[3] = rx_phy_empty_3; end endgenerate generate if (NUM_OF_LANES > 3) begin assign rx_phy_align_en_3 = rx_ip_align_en[3]; assign rx_phy_lane_polarity_3 = rx_ip_lane_polarity[3]; assign rx_phy_lane_powerdown_3 = rx_ip_lane_powerdown[3]; assign rx_phy_analogreset_3 = rx_core_analogreset[3]; assign rx_phy_digitalreset_3 = rx_core_digitalreset[3]; end else begin assign rx_phy_align_en_3 = 1'd0; assign rx_phy_lane_polarity_3 = 1'd0; assign rx_phy_lane_powerdown_3 = 1'd0; assign rx_phy_analogreset_3 = 1'd1; assign rx_phy_digitalreset_3 = 1'd1; end endgenerate assign rx_phy_bit_reversal_3 = rx_ip_bit_reversal; assign rx_phy_byte_reversal_3 = rx_ip_byte_reversal; generate if (NUM_OF_LANES > 4) begin assign rx_core_locked[4] = rx_phy_locked_4; assign rx_core_cal_busy[4] = rx_phy_cal_busy_4; assign rx_ip_locked[4] = rx_phy_locked_4; assign rx_ip_cal_busy[4] = rx_phy_cal_busy_4; assign rx_ip_valid[4] = rx_phy_valid_4; assign rx_ip_data[((32*5)-1):(32*4)] = rx_phy_data_4; assign rx_ip_disperr[((4*5)-1):(4*4)] = rx_phy_disperr_4; assign rx_ip_deterr[((4*5)-1):(4*4)] = rx_phy_deterr_4; assign rx_ip_kchar[((4*5)-1):(4*4)] = rx_phy_kchar_4; assign rx_ip_full[4] = rx_phy_full_4; assign rx_ip_empty[4] = rx_phy_empty_4; end endgenerate generate if (NUM_OF_LANES > 4) begin assign rx_phy_align_en_4 = rx_ip_align_en[4]; assign rx_phy_lane_polarity_4 = rx_ip_lane_polarity[4]; assign rx_phy_lane_powerdown_4 = rx_ip_lane_powerdown[4]; assign rx_phy_analogreset_4 = rx_core_analogreset[4]; assign rx_phy_digitalreset_4 = rx_core_digitalreset[4]; end else begin assign rx_phy_align_en_4 = 1'd0; assign rx_phy_lane_polarity_4 = 1'd0; assign rx_phy_lane_powerdown_4 = 1'd0; assign rx_phy_analogreset_4 = 1'd1; assign rx_phy_digitalreset_4 = 1'd1; end endgenerate assign rx_phy_bit_reversal_4 = rx_ip_bit_reversal; assign rx_phy_byte_reversal_4 = rx_ip_byte_reversal; generate if (NUM_OF_LANES > 5) begin assign rx_core_locked[5] = rx_phy_locked_5; assign rx_core_cal_busy[5] = rx_phy_cal_busy_5; assign rx_ip_locked[5] = rx_phy_locked_5; assign rx_ip_cal_busy[5] = rx_phy_cal_busy_5; assign rx_ip_valid[5] = rx_phy_valid_5; assign rx_ip_data[((32*6)-1):(32*5)] = rx_phy_data_5; assign rx_ip_disperr[((4*6)-1):(4*5)] = rx_phy_disperr_5; assign rx_ip_deterr[((4*6)-1):(4*5)] = rx_phy_deterr_5; assign rx_ip_kchar[((4*6)-1):(4*5)] = rx_phy_kchar_5; assign rx_ip_full[5] = rx_phy_full_5; assign rx_ip_empty[5] = rx_phy_empty_5; end endgenerate generate if (NUM_OF_LANES > 5) begin assign rx_phy_align_en_5 = rx_ip_align_en[5]; assign rx_phy_lane_polarity_5 = rx_ip_lane_polarity[5]; assign rx_phy_lane_powerdown_5 = rx_ip_lane_powerdown[5]; assign rx_phy_analogreset_5 = rx_core_analogreset[5]; assign rx_phy_digitalreset_5 = rx_core_digitalreset[5]; end else begin assign rx_phy_align_en_5 = 1'd0; assign rx_phy_lane_polarity_5 = 1'd0; assign rx_phy_lane_powerdown_5 = 1'd0; assign rx_phy_analogreset_5 = 1'd1; assign rx_phy_digitalreset_5 = 1'd1; end endgenerate assign rx_phy_bit_reversal_5 = rx_ip_bit_reversal; assign rx_phy_byte_reversal_5 = rx_ip_byte_reversal; generate if (NUM_OF_LANES > 6) begin assign rx_core_locked[6] = rx_phy_locked_6; assign rx_core_cal_busy[6] = rx_phy_cal_busy_6; assign rx_ip_locked[6] = rx_phy_locked_6; assign rx_ip_cal_busy[6] = rx_phy_cal_busy_6; assign rx_ip_valid[6] = rx_phy_valid_6; assign rx_ip_data[((32*7)-1):(32*6)] = rx_phy_data_6; assign rx_ip_disperr[((4*7)-1):(4*6)] = rx_phy_disperr_6; assign rx_ip_deterr[((4*7)-1):(4*6)] = rx_phy_deterr_6; assign rx_ip_kchar[((4*7)-1):(4*6)] = rx_phy_kchar_6; assign rx_ip_full[6] = rx_phy_full_6; assign rx_ip_empty[6] = rx_phy_empty_6; end endgenerate generate if (NUM_OF_LANES > 6) begin assign rx_phy_align_en_6 = rx_ip_align_en[6]; assign rx_phy_lane_polarity_6 = rx_ip_lane_polarity[6]; assign rx_phy_lane_powerdown_6 = rx_ip_lane_powerdown[6]; assign rx_phy_analogreset_6 = rx_core_analogreset[6]; assign rx_phy_digitalreset_6 = rx_core_digitalreset[6]; end else begin assign rx_phy_align_en_6 = 1'd0; assign rx_phy_lane_polarity_6 = 1'd0; assign rx_phy_lane_powerdown_6 = 1'd0; assign rx_phy_analogreset_6 = 1'd1; assign rx_phy_digitalreset_6 = 1'd1; end endgenerate assign rx_phy_bit_reversal_6 = rx_ip_bit_reversal; assign rx_phy_byte_reversal_6 = rx_ip_byte_reversal; generate if (NUM_OF_LANES > 7) begin assign rx_core_locked[7] = rx_phy_locked_7; assign rx_core_cal_busy[7] = rx_phy_cal_busy_7; assign rx_ip_locked[7] = rx_phy_locked_7; assign rx_ip_cal_busy[7] = rx_phy_cal_busy_7; assign rx_ip_valid[7] = rx_phy_valid_7; assign rx_ip_data[((32*8)-1):(32*7)] = rx_phy_data_7; assign rx_ip_disperr[((4*8)-1):(4*7)] = rx_phy_disperr_7; assign rx_ip_deterr[((4*8)-1):(4*7)] = rx_phy_deterr_7; assign rx_ip_kchar[((4*8)-1):(4*7)] = rx_phy_kchar_7; assign rx_ip_full[7] = rx_phy_full_7; assign rx_ip_empty[7] = rx_phy_empty_7; end endgenerate generate if (NUM_OF_LANES > 7) begin assign rx_phy_align_en_7 = rx_ip_align_en[7]; assign rx_phy_lane_polarity_7 = rx_ip_lane_polarity[7]; assign rx_phy_lane_powerdown_7 = rx_ip_lane_powerdown[7]; assign rx_phy_analogreset_7 = rx_core_analogreset[7]; assign rx_phy_digitalreset_7 = rx_core_digitalreset[7]; end else begin assign rx_phy_align_en_7 = 1'd0; assign rx_phy_lane_polarity_7 = 1'd0; assign rx_phy_lane_powerdown_7 = 1'd0; assign rx_phy_analogreset_7 = 1'd1; assign rx_phy_digitalreset_7 = 1'd1; end endgenerate assign rx_phy_bit_reversal_7 = rx_ip_bit_reversal; assign rx_phy_byte_reversal_7 = rx_ip_byte_reversal; // tx assignments generate if (NUM_OF_LANES > 0) begin assign tx_core_cal_busy[0] = tx_phy_cal_busy_0; assign tx_ip_cal_busy[0] = tx_phy_cal_busy_0; assign tx_ip_full[0] = tx_phy_full_0; assign tx_ip_empty[0] = tx_phy_empty_0; end endgenerate generate if (NUM_OF_LANES > 0) begin assign tx_phy_data_0 = tx_ip_data[((32*1)-1):(32*0)]; assign tx_phy_kchar_0 = tx_ip_kchar[((4*1)-1):(4*0)]; assign tx_phy_elecidle_0 = tx_ip_elecidle[0]; assign tx_phy_lane_polarity_0 = tx_ip_lane_polarity[0]; assign tx_phy_lane_powerdown_0 = tx_ip_lane_powerdown[0]; end else begin assign tx_phy_data_0 = 32'd0; assign tx_phy_kchar_0 = 4'd0; assign tx_phy_elecidle_0 = 1'd0; assign tx_phy_lane_polarity_0 = 1'd0; assign tx_phy_lane_powerdown_0 = 1'd0; end endgenerate generate if (NUM_OF_LANES > 0) begin assign tx_phy_analogreset_0 = tx_core_analogreset[0]; assign tx_phy_digitalreset_0 = tx_core_digitalreset[0]; end else begin assign tx_phy_analogreset_0 = 1'd1; assign tx_phy_digitalreset_0 = 1'd1; end endgenerate assign tx_phy_bit_reversal_0 = tx_ip_bit_reversal; assign tx_phy_byte_reversal_0 = tx_ip_byte_reversal; generate if (NUM_OF_LANES > 1) begin assign tx_core_cal_busy[1] = tx_phy_cal_busy_1; assign tx_ip_cal_busy[1] = tx_phy_cal_busy_1; assign tx_ip_full[1] = tx_phy_full_1; assign tx_ip_empty[1] = tx_phy_empty_1; end endgenerate generate if (NUM_OF_LANES > 1) begin assign tx_phy_data_1 = tx_ip_data[((32*2)-1):(32*1)]; assign tx_phy_kchar_1 = tx_ip_kchar[((4*2)-1):(4*1)]; assign tx_phy_elecidle_1 = tx_ip_elecidle[1]; assign tx_phy_lane_polarity_1 = tx_ip_lane_polarity[1]; assign tx_phy_lane_powerdown_1 = tx_ip_lane_powerdown[1]; end else begin assign tx_phy_data_1 = 32'd0; assign tx_phy_kchar_1 = 4'd0; assign tx_phy_elecidle_1 = 1'd0; assign tx_phy_lane_polarity_1 = 1'd0; assign tx_phy_lane_powerdown_1 = 1'd0; end endgenerate generate if (NUM_OF_LANES > 1) begin assign tx_phy_analogreset_1 = tx_core_analogreset[1]; assign tx_phy_digitalreset_1 = tx_core_digitalreset[1]; end else begin assign tx_phy_analogreset_1 = 1'd1; assign tx_phy_digitalreset_1 = 1'd1; end endgenerate assign tx_phy_bit_reversal_1 = tx_ip_bit_reversal; assign tx_phy_byte_reversal_1 = tx_ip_byte_reversal; generate if (NUM_OF_LANES > 2) begin assign tx_core_cal_busy[2] = tx_phy_cal_busy_2; assign tx_ip_cal_busy[2] = tx_phy_cal_busy_2; assign tx_ip_full[2] = tx_phy_full_2; assign tx_ip_empty[2] = tx_phy_empty_2; end endgenerate generate if (NUM_OF_LANES > 2) begin assign tx_phy_data_2 = tx_ip_data[((32*3)-1):(32*2)]; assign tx_phy_kchar_2 = tx_ip_kchar[((4*3)-1):(4*2)]; assign tx_phy_elecidle_2 = tx_ip_elecidle[2]; assign tx_phy_lane_polarity_2 = tx_ip_lane_polarity[2]; assign tx_phy_lane_powerdown_2 = tx_ip_lane_powerdown[2]; end else begin assign tx_phy_data_2 = 32'd0; assign tx_phy_kchar_2 = 4'd0; assign tx_phy_elecidle_2 = 1'd0; assign tx_phy_lane_polarity_2 = 1'd0; assign tx_phy_lane_powerdown_2 = 1'd0; end endgenerate generate if (NUM_OF_LANES > 2) begin assign tx_phy_analogreset_2 = tx_core_analogreset[2]; assign tx_phy_digitalreset_2 = tx_core_digitalreset[2]; end else begin assign tx_phy_analogreset_2 = 1'd1; assign tx_phy_digitalreset_2 = 1'd1; end endgenerate assign tx_phy_bit_reversal_2 = tx_ip_bit_reversal; assign tx_phy_byte_reversal_2 = tx_ip_byte_reversal; generate if (NUM_OF_LANES > 3) begin assign tx_core_cal_busy[3] = tx_phy_cal_busy_3; assign tx_ip_cal_busy[3] = tx_phy_cal_busy_3; assign tx_ip_full[3] = tx_phy_full_3; assign tx_ip_empty[3] = tx_phy_empty_3; end endgenerate generate if (NUM_OF_LANES > 3) begin assign tx_phy_data_3 = tx_ip_data[((32*4)-1):(32*3)]; assign tx_phy_kchar_3 = tx_ip_kchar[((4*4)-1):(4*3)]; assign tx_phy_elecidle_3 = tx_ip_elecidle[3]; assign tx_phy_lane_polarity_3 = tx_ip_lane_polarity[3]; assign tx_phy_lane_powerdown_3 = tx_ip_lane_powerdown[3]; end else begin assign tx_phy_data_3 = 32'd0; assign tx_phy_kchar_3 = 4'd0; assign tx_phy_elecidle_3 = 1'd0; assign tx_phy_lane_polarity_3 = 1'd0; assign tx_phy_lane_powerdown_3 = 1'd0; end endgenerate generate if (NUM_OF_LANES > 3) begin assign tx_phy_analogreset_3 = tx_core_analogreset[3]; assign tx_phy_digitalreset_3 = tx_core_digitalreset[3]; end else begin assign tx_phy_analogreset_3 = 1'd1; assign tx_phy_digitalreset_3 = 1'd1; end endgenerate assign tx_phy_bit_reversal_3 = tx_ip_bit_reversal; assign tx_phy_byte_reversal_3 = tx_ip_byte_reversal; generate if (NUM_OF_LANES > 4) begin assign tx_core_cal_busy[4] = tx_phy_cal_busy_4; assign tx_ip_cal_busy[4] = tx_phy_cal_busy_4; assign tx_ip_full[4] = tx_phy_full_4; assign tx_ip_empty[4] = tx_phy_empty_4; end endgenerate generate if (NUM_OF_LANES > 4) begin assign tx_phy_data_4 = tx_ip_data[((32*5)-1):(32*4)]; assign tx_phy_kchar_4 = tx_ip_kchar[((4*5)-1):(4*4)]; assign tx_phy_elecidle_4 = tx_ip_elecidle[4]; assign tx_phy_lane_polarity_4 = tx_ip_lane_polarity[4]; assign tx_phy_lane_powerdown_4 = tx_ip_lane_powerdown[4]; end else begin assign tx_phy_data_4 = 32'd0; assign tx_phy_kchar_4 = 4'd0; assign tx_phy_elecidle_4 = 1'd0; assign tx_phy_lane_polarity_4 = 1'd0; assign tx_phy_lane_powerdown_4 = 1'd0; end endgenerate generate if (NUM_OF_LANES > 4) begin assign tx_phy_analogreset_4 = tx_core_analogreset[4]; assign tx_phy_digitalreset_4 = tx_core_digitalreset[4]; end else begin assign tx_phy_analogreset_4 = 1'd1; assign tx_phy_digitalreset_4 = 1'd1; end endgenerate assign tx_phy_bit_reversal_4 = tx_ip_bit_reversal; assign tx_phy_byte_reversal_4 = tx_ip_byte_reversal; generate if (NUM_OF_LANES > 5) begin assign tx_core_cal_busy[5] = tx_phy_cal_busy_5; assign tx_ip_cal_busy[5] = tx_phy_cal_busy_5; assign tx_ip_full[5] = tx_phy_full_5; assign tx_ip_empty[5] = tx_phy_empty_5; end endgenerate generate if (NUM_OF_LANES > 5) begin assign tx_phy_data_5 = tx_ip_data[((32*6)-1):(32*5)]; assign tx_phy_kchar_5 = tx_ip_kchar[((4*6)-1):(4*5)]; assign tx_phy_elecidle_5 = tx_ip_elecidle[5]; assign tx_phy_lane_polarity_5 = tx_ip_lane_polarity[5]; assign tx_phy_lane_powerdown_5 = tx_ip_lane_powerdown[5]; end else begin assign tx_phy_data_5 = 32'd0; assign tx_phy_kchar_5 = 4'd0; assign tx_phy_elecidle_5 = 1'd0; assign tx_phy_lane_polarity_5 = 1'd0; assign tx_phy_lane_powerdown_5 = 1'd0; end endgenerate generate if (NUM_OF_LANES > 5) begin assign tx_phy_analogreset_5 = tx_core_analogreset[5]; assign tx_phy_digitalreset_5 = tx_core_digitalreset[5]; end else begin assign tx_phy_analogreset_5 = 1'd1; assign tx_phy_digitalreset_5 = 1'd1; end endgenerate assign tx_phy_bit_reversal_5 = tx_ip_bit_reversal; assign tx_phy_byte_reversal_5 = tx_ip_byte_reversal; generate if (NUM_OF_LANES > 6) begin assign tx_core_cal_busy[6] = tx_phy_cal_busy_6; assign tx_ip_cal_busy[6] = tx_phy_cal_busy_6; assign tx_ip_full[6] = tx_phy_full_6; assign tx_ip_empty[6] = tx_phy_empty_6; end endgenerate generate if (NUM_OF_LANES > 6) begin assign tx_phy_data_6 = tx_ip_data[((32*7)-1):(32*6)]; assign tx_phy_kchar_6 = tx_ip_kchar[((4*7)-1):(4*6)]; assign tx_phy_elecidle_6 = tx_ip_elecidle[6]; assign tx_phy_lane_polarity_6 = tx_ip_lane_polarity[6]; assign tx_phy_lane_powerdown_6 = tx_ip_lane_powerdown[6]; end else begin assign tx_phy_data_6 = 32'd0; assign tx_phy_kchar_6 = 4'd0; assign tx_phy_elecidle_6 = 1'd0; assign tx_phy_lane_polarity_6 = 1'd0; assign tx_phy_lane_powerdown_6 = 1'd0; end endgenerate generate if (NUM_OF_LANES > 6) begin assign tx_phy_analogreset_6 = tx_core_analogreset[6]; assign tx_phy_digitalreset_6 = tx_core_digitalreset[6]; end else begin assign tx_phy_analogreset_6 = 1'd1; assign tx_phy_digitalreset_6 = 1'd1; end endgenerate assign tx_phy_bit_reversal_6 = tx_ip_bit_reversal; assign tx_phy_byte_reversal_6 = tx_ip_byte_reversal; generate if (NUM_OF_LANES > 7) begin assign tx_core_cal_busy[7] = tx_phy_cal_busy_7; assign tx_ip_cal_busy[7] = tx_phy_cal_busy_7; assign tx_ip_full[7] = tx_phy_full_7; assign tx_ip_empty[7] = tx_phy_empty_7; end endgenerate generate if (NUM_OF_LANES > 7) begin assign tx_phy_data_7 = tx_ip_data[((32*8)-1):(32*7)]; assign tx_phy_kchar_7 = tx_ip_kchar[((4*8)-1):(4*7)]; assign tx_phy_elecidle_7 = tx_ip_elecidle[7]; assign tx_phy_lane_polarity_7 = tx_ip_lane_polarity[7]; assign tx_phy_lane_powerdown_7 = tx_ip_lane_powerdown[7]; end else begin assign tx_phy_data_7 = 32'd0; assign tx_phy_kchar_7 = 4'd0; assign tx_phy_elecidle_7 = 1'd0; assign tx_phy_lane_polarity_7 = 1'd0; assign tx_phy_lane_powerdown_7 = 1'd0; end endgenerate generate if (NUM_OF_LANES > 7) begin assign tx_phy_analogreset_7 = tx_core_analogreset[7]; assign tx_phy_digitalreset_7 = tx_core_digitalreset[7]; end else begin assign tx_phy_analogreset_7 = 1'd1; assign tx_phy_digitalreset_7 = 1'd1; end endgenerate assign tx_phy_bit_reversal_7 = tx_ip_bit_reversal; assign tx_phy_byte_reversal_7 = tx_ip_byte_reversal; endmodule