mirror of
https://github.com/gnss-sdr/gnss-sdr
synced 2024-11-17 15:24:56 +00:00
515 lines
16 KiB
C++
515 lines
16 KiB
C++
/*!
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* \file raw_array_impl.cc
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* \brief GNU Radio source block to acces to experimental GNSS Array platform.
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* \author Javier Arribas, 2014. jarribas(at)cttc.es
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*
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* -------------------------------------------------------------------------
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*
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* Copyright (C) 2010-2015 (see AUTHORS file for a list of contributors)
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*
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* GNSS-SDR is a software defined Global Navigation
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* Satellite Systems receiver
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*
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* This file is part of GNSS-SDR.
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*
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* GNSS-SDR is free software: you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation, either version 3 of the License, or
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* (at your option) any later version.
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*
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* GNSS-SDR is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with GNSS-SDR. If not, see <http://www.gnu.org/licenses/>.
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*
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* -------------------------------------------------------------------------
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*/
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#ifdef HAVE_CONFIG_H
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#include "config.h"
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#endif
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#include <gnuradio/io_signature.h>
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#include "raw_array_impl.h"
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#include <arpa/inet.h>
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#include <net/if.h>
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#include <net/ethernet.h>
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#include <netinet/if_ether.h>
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#include <sys/ioctl.h>
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#include <string.h>
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#include <stdlib.h>
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#define FIFO_SIZE 1000000
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#define DBFCTTC_NUM_CHANNELS 8
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namespace gr {
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namespace dbfcttc {
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raw_array::sptr
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raw_array::make(const char *src_device,short number_of_channels, int snapshots_per_frame, int inter_frame_delay, int sampling_freq)
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{
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return gnuradio::get_initial_sptr
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(new raw_array_impl(src_device, number_of_channels, snapshots_per_frame, inter_frame_delay, sampling_freq));
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}
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/*
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* The private constructor
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*/
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raw_array_impl::raw_array_impl(const char *src_device,short number_of_channels, int snapshots_per_frame, int inter_frame_delay, int sampling_freq)
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: gr::sync_block("raw_array",
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gr::io_signature::make(0, 0, 0),
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gr::io_signature::make(8, 8, sizeof(gr_complex)))
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{
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// constructor code here
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fprintf(stdout,"DBFCTTC Start\n");
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d_src_device=src_device;
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d_number_of_channels=number_of_channels;
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d_snapshots_per_frame=snapshots_per_frame;
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d_inter_frame_delay=inter_frame_delay;
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d_sampling_freq=sampling_freq;
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d_flag_start_frame=true;
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d_fifo_full=false;
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d_last_frame_counter=0;
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d_num_rx_errors=0;
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flag_16_bits_sample=true;
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//allocate signal samples buffer
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//TODO: Check memory pointers
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fifo_buff_ch=new gr_complex*[DBFCTTC_NUM_CHANNELS];
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for (int i=0;i<DBFCTTC_NUM_CHANNELS;i++)
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{
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fifo_buff_ch[i]=new gr_complex[FIFO_SIZE];
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}
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fifo_read_ptr=0;
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fifo_write_ptr=0;
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fifo_items=0;
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//open the ethernet device
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if (open()==true)
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{
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// start pcap capture thread
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d_pcap_thread=new boost::thread(boost::bind(&raw_array_impl::my_pcap_loop_thread,this,descr));
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// send array configuration frame
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if (configure_array()==true)
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{
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if (start_array()==true)
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{
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printf("Array ready!\n");
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}else{
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exit(1); //ethernet error!
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}
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}else{
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exit(1); //ethernet error!
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}
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}else{
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exit(1); //ethernet error!
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}
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}
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bool raw_array_impl::open()
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{
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char errbuf[PCAP_ERRBUF_SIZE];
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boost::mutex::scoped_lock lock(d_mutex); // hold mutex for duration of this function
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char *dev;
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/* open device for reading */
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descr = pcap_open_live(d_src_device,1500,1,1000,errbuf);
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if(descr == NULL)
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{
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printf("Error openning ethernet device: %s\n",d_src_device);
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printf("Fatal Error in pcap_open_live(): %s\n",errbuf);
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return false;
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}
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return true;
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}
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bool raw_array_impl::configure_array()
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{
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//prepare the config data for the ethernet frame
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// note: command=1 -> beamforming config
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// command=2 -> start
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// command=3 -> stop
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// command=4 -> raw array config
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char data[20];
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for(int i=0;i<20;i++)
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{
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data[i]=0x00;
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}
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data[0]=4; //command to activate RAW array
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data[1]=d_number_of_channels;
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data[2]=d_snapshots_per_frame>>8;
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data[3]=d_snapshots_per_frame & 255;
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printf("\n Total bytes in snapshots payload = %i\n",d_snapshots_per_frame*d_number_of_channels*2);
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printf("\n Estimated eth RAW frame size [bytes] %i\n",12+2+3+d_snapshots_per_frame*d_number_of_channels*2+1);
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data[4]=d_inter_frame_delay>>8;
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data[5]=d_inter_frame_delay & 255;
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data[6]=0xB;
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data[7]=0xF;
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//send the frame
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struct ether_header myheader;
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myheader.ether_type=0xbfcd; //this is the ethenet layer II protocol ID for the CTTC array hardware
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memset(myheader.ether_dhost,0xff,sizeof(myheader.ether_dhost));
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memset(myheader.ether_shost,0x11,sizeof(myheader.ether_shost));
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unsigned char frame[sizeof(struct ether_header)+sizeof(data)];
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memcpy(frame,&myheader,sizeof(struct ether_header));
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memcpy(frame+sizeof(struct ether_header),&data,sizeof(data));
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if (pcap_inject(descr,frame,sizeof(frame))==-1) {
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printf("Error sending configuration packet\n");
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pcap_perror(descr,0);
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return false;
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}else{
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printf("Sent configuration packet OK\n");
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return true;
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}
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}
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bool raw_array_impl::start_array()
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{
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char data[20];
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for(int i=0;i<20;i++)
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{
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data[i]=0x00;
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}
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data[0]=2; //command to start the array operation (configured previously)
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//send the frame
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struct ether_header myheader;
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myheader.ether_type=0xbfcd; //this is the ethenet layer II protocol ID for the CTTC array hardware
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memset(myheader.ether_dhost,0xff,sizeof(myheader.ether_dhost));
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memset(myheader.ether_shost,0x11,sizeof(myheader.ether_shost));
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unsigned char frame[sizeof(struct ether_header)+sizeof(data)];
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memcpy(frame,&myheader,sizeof(struct ether_header));
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memcpy(frame+sizeof(struct ether_header),&data,sizeof(data));
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if (pcap_inject(descr,frame,sizeof(frame))==-1) {
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printf("Error sending start packet\n");
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pcap_perror(descr,0);
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return false;
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}else{
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printf("Sent start packet OK\n");
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return true;
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}
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}
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bool raw_array_impl::stop_array()
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{
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char data[20];
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for(int i=0;i<20;i++)
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{
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data[i]=0x00;
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}
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data[0]=3; //command to stop the array operation (configured previously)
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//send the frame
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struct ether_header myheader;
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myheader.ether_type=0xbfcd; //this is the ethenet layer II protocol ID for the CTTC array hardware
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memset(myheader.ether_dhost,0xff,sizeof(myheader.ether_dhost));
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memset(myheader.ether_shost,0x11,sizeof(myheader.ether_shost));
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unsigned char frame[sizeof(struct ether_header)+sizeof(data)];
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memcpy(frame,&myheader,sizeof(struct ether_header));
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memcpy(frame+sizeof(struct ether_header),&data,sizeof(data));
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if (pcap_inject(descr,frame,sizeof(frame))==-1) {
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printf("Error sending stop packet\n");
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pcap_perror(descr,0);
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return false;
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}else{
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printf("Sent stop packet OK\n");
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return true;
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}
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}
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/*
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* Our virtual destructor.
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*/
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raw_array_impl::~raw_array_impl()
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{
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// destructor code here
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if (stop_array()==true)
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{
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printf("Array stopped!\n");
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}else{
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exit(1); //ethernet error!
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}
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if(descr != NULL)
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{
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pcap_breakloop(descr);
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d_pcap_thread->join();
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pcap_close(descr);
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}
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for (int i=0;i<DBFCTTC_NUM_CHANNELS;i++)
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{
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delete[] fifo_buff_ch[i];
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}
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delete fifo_buff_ch;
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fprintf(stdout,"All stopped OK\n");
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}
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void raw_array_impl::static_pcap_callback(u_char *args, const struct pcap_pkthdr* pkthdr,
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const u_char* packet)
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{
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//
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raw_array_impl *bridge=(raw_array_impl*) args;
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bridge->pcap_callback(args, pkthdr, packet);
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}
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void raw_array_impl::pcap_callback(u_char *args, const struct pcap_pkthdr* pkthdr,
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const u_char* packet)
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{
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boost::mutex::scoped_lock lock(d_mutex); // hold mutex for duration of this function
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int numframebyte;
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short int real,imag;
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// eth frame parameters
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int number_of_channels;
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unsigned short int snapshots_per_frame;
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// **** CTTC DBF PACKET DECODER ****
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if ((packet[12]==0xCD) & (packet[13]==0xBF))
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{
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//printf(".");
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// control parameters
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number_of_channels=(int)packet[14];
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//std::cout<<"number_of_channels="<<number_of_channels<<std::endl;
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snapshots_per_frame=packet[15] << 8 | packet[16];
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//std::cout<<"snapshots_per_frame="<<snapshots_per_frame<<std::endl;
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//frame counter check for overflows!
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numframebyte=(unsigned char)packet[16+snapshots_per_frame*2*number_of_channels+1];
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//std::cout<<"numframebyte="<<numframebyte<<std::endl;
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//Overflow detector and mitigator
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if (d_flag_start_frame == true)
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{
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d_last_frame_counter=numframebyte;
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d_flag_start_frame=false;
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}else{
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if ((d_last_frame_counter-numframebyte)>1)
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{
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int missing_frames=abs(d_last_frame_counter-numframebyte);
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if (missing_frames!=255 )
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{
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//fake samples generation to help tracking loops
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std::complex<float> last_sample[DBFCTTC_NUM_CHANNELS];
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if (fifo_write_ptr == 0)
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{
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for (int ch=0;ch<number_of_channels;ch++)
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{
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last_sample[ch]=fifo_buff_ch[ch][FIFO_SIZE];
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}
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}else{
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for (int ch=0;ch<number_of_channels;ch++)
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{
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last_sample[ch]=fifo_buff_ch[ch][fifo_write_ptr-1];
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}
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}
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for(int i=0;i<(snapshots_per_frame*missing_frames);i++)
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{
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if (fifo_items <= FIFO_SIZE) {
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for (int ch=0;ch<number_of_channels;ch++)
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{
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fifo_buff_ch[ch][fifo_write_ptr] = last_sample[ch];
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}
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fifo_write_ptr++;
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if (fifo_write_ptr == FIFO_SIZE) fifo_write_ptr = 0;
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fifo_items++;
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if (d_fifo_full==true)
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{
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d_fifo_full=false;
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}
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}else{
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if (d_fifo_full==false)
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{
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printf("FIFO full\n");
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fflush(stdout);
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d_fifo_full=true;
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}
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}
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}
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d_num_rx_errors=d_num_rx_errors + 1;
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printf("RAW Array driver overflow RX %d\n",numframebyte);
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}
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}
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}
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d_last_frame_counter=numframebyte;
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};
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//snapshots reading..
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for(int i=0;i<snapshots_per_frame;i++)
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{
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if (fifo_items <= FIFO_SIZE) {
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for (int ch=0;ch<number_of_channels;ch++)
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{
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if (flag_16_bits_sample==true)
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{
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//(2i+2q)*8channels =32 bytes
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real=(signed short int)(packet[17 + ch*4 + i * 32] << 8 | packet[17 + ch*4 + 1 + i * 32]);
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imag=(signed short int)(packet[17 + ch*4 + 2 + i * 32] << 8 | packet[17 + ch*4 + 3 + i * 32]);
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}else{
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//(1i+1q)*8channels =16 bytes
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real = (signed char)packet[17 + ch*2 + i * 16];
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imag = (signed char)packet[17 + ch*2 + 1 + i * 16];
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}
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//todo: invert IQ in FPGA
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//fifo_buff_ch[ch][fifo_write_ptr] = std::complex<float>(real, imag);
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fifo_buff_ch[ch][fifo_write_ptr] = std::complex<float>(imag, real); //inverted due to inversion in front-end
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//std::cout<<"["<<ch<<"]["<<fifo_write_ptr<<"]"<<fifo_buff_ch[ch][fifo_write_ptr]<<std::endl;
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}
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fifo_write_ptr++;
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if (fifo_write_ptr == FIFO_SIZE) fifo_write_ptr = 0;
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fifo_items++;
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if (d_fifo_full==true)
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{
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d_fifo_full=false;
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}
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}else{
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if (d_fifo_full==false)
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{
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printf("FIFO full\n");
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fflush(stdout);
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d_fifo_full=true;
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}
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}
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}
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//test RX
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// **** CTTC DBF PACKET DECODER ***
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//else{
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//std::cout<<"RX PKT ID="<<(int)packet[12]<<","<<(int)packet[13]<<std::endl;
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//}
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// // *** END CTTC DBF PACKET DECODER ***
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}
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void raw_array_impl::my_pcap_loop_thread(pcap_t *pcap_handle)
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{
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pcap_loop(pcap_handle, -1, raw_array_impl::static_pcap_callback, (u_char *)this);
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}
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int
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raw_array_impl::work(int noutput_items,
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gr_vector_const_void_star &input_items,
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gr_vector_void_star &output_items)
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{
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//gr_complex *out = (gr_complex *) output_items[0];
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// channel output buffers
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// gr_complex *ch1 = (gr_complex *) output_items[0];
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// gr_complex *ch2 = (gr_complex *) output_items[1];
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// gr_complex *ch3 = (gr_complex *) output_items[2];
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// gr_complex *ch4 = (gr_complex *) output_items[3];
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// gr_complex *ch5 = (gr_complex *) output_items[4];
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// gr_complex *ch6 = (gr_complex *) output_items[5];
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// gr_complex *ch7 = (gr_complex *) output_items[6];
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// gr_complex *ch8 = (gr_complex *) output_items[7];
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// send samples to next GNU Radio block
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boost::mutex::scoped_lock lock(d_mutex); // hold mutex for duration of this function
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int num_samples_readed;
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if (noutput_items<fifo_items)
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{
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num_samples_readed=noutput_items;//read all
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}else{
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num_samples_readed=fifo_items;//read what we have
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}
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int aligned_read_items=FIFO_SIZE-fifo_read_ptr;
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if (aligned_read_items>=num_samples_readed)
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{
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//read all in a single memcpy
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for (int ch=0;ch<DBFCTTC_NUM_CHANNELS;ch++)
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{
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//((gr_complex*)output_items[ch])[i]=fifo_buff_ch[ch][fifo_read_ptr];
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memcpy(&((gr_complex*)output_items[ch])[0],&fifo_buff_ch[ch][fifo_read_ptr],sizeof(std::complex<float> )*num_samples_readed);
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}
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fifo_read_ptr=fifo_read_ptr+num_samples_readed; //increase the fifo pointer
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if (fifo_read_ptr==FIFO_SIZE) fifo_read_ptr=0;
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}else{
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//two step wrap read
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for (int ch=0;ch<DBFCTTC_NUM_CHANNELS;ch++)
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{
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//((gr_complex*)output_items[ch])[i]=fifo_buff_ch[ch][fifo_read_ptr];
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memcpy(&((gr_complex*)output_items[ch])[0],&fifo_buff_ch[ch][fifo_read_ptr],sizeof(std::complex<float> )*aligned_read_items);
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}
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fifo_read_ptr=fifo_read_ptr+aligned_read_items; //increase the fifo pointer
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if (fifo_read_ptr==FIFO_SIZE) fifo_read_ptr=0;
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for (int ch=0;ch<DBFCTTC_NUM_CHANNELS;ch++)
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{
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//((gr_complex*)output_items[ch])[i]=fifo_buff_ch[ch][fifo_read_ptr];
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memcpy(&((gr_complex*)output_items[ch])[aligned_read_items],&fifo_buff_ch[ch][fifo_read_ptr],sizeof(std::complex<float>)*(num_samples_readed-aligned_read_items));
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}
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fifo_read_ptr=fifo_read_ptr+(num_samples_readed-aligned_read_items); //increase the fifo pointer
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}
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fifo_items=fifo_items-num_samples_readed;
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// int num_samples_readed=0;
|
|
// for(int i=0;i<noutput_items;i++)
|
|
// {
|
|
//
|
|
// if (fifo_items > 0) {
|
|
// //TODO: optimize-me with memcpy!!
|
|
// for (int ch=0;ch<DBFCTTC_NUM_CHANNELS;ch++)
|
|
// {
|
|
// ((gr_complex*)output_items[ch])[i]=fifo_buff_ch[ch][fifo_read_ptr];
|
|
// }
|
|
// fifo_read_ptr++;
|
|
// if (fifo_read_ptr==FIFO_SIZE) fifo_read_ptr=0;
|
|
// fifo_items--;
|
|
// num_samples_readed++;
|
|
// } else {
|
|
// break;
|
|
// }
|
|
//
|
|
// }
|
|
|
|
// Tell runtime system how many output items we produced.
|
|
return num_samples_readed;
|
|
}
|
|
|
|
} /* namespace dbfcttc */
|
|
} /* namespace gr */
|
|
|