/* -*- c++ -*- */ /* * Copyright 2007 Free Software Foundation, Inc. * * This file is part of GNU Radio * * GNU Radio is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 3, or (at your option) * any later version. * * GNU Radio 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. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License along * with this program; if not, write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. */ #ifdef HAVE_CONFIG_H #include #endif #include #include #include // QA only #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define NBPING 10 static bool verbose = true; bool bskip = false; long bstep = 10000; long bcurr = 0; long incr = 0x500; long ptime = 0x000; class test_usrp_inband_timestamps : public mb_mblock { mb_port_sptr d_tx; mb_port_sptr d_rx; mb_port_sptr d_cs; pmt_t d_tx_chan; // returned tx channel handle pmt_t d_rx_chan; // returned tx channel handle struct timeval times[NBPING]; enum state_t { INIT, OPENING_USRP, ALLOCATING_CHANNEL, TRANSMITTING, CLOSING_CHANNEL, CLOSING_USRP, }; state_t d_state; long d_nsamples_to_send; long d_nsamples_xmitted; long d_nframes_xmitted; long d_samples_per_frame; bool d_done_sending; // for generating sine wave output ui_nco d_nco; double d_amplitude; public: test_usrp_inband_timestamps(mb_runtime *runtime, const std::string &instance_name, pmt_t user_arg); ~test_usrp_inband_timestamps(); void initial_transition(); void handle_message(mb_message_sptr msg); protected: void open_usrp(); void close_usrp(); void allocate_channel(); void send_packets(); void enter_receiving(); void enter_transmitting(); void build_and_send_ping(); void build_and_send_next_frame(); void handle_xmit_response(pmt_t invocation_handle); void enter_closing_channel(); }; test_usrp_inband_timestamps::test_usrp_inband_timestamps(mb_runtime *runtime, const std::string &instance_name, pmt_t user_arg) : mb_mblock(runtime, instance_name, user_arg), d_tx_chan(PMT_NIL), d_rx_chan(PMT_NIL), d_state(INIT), d_nsamples_to_send((long) 40e6), d_nsamples_xmitted(0), d_nframes_xmitted(0), //d_samples_per_frame((long)(126)), d_samples_per_frame((long)(126 * 2)), // non-full packet //d_samples_per_frame((long)(126 * 3.5)), // non-full packet //d_samples_per_frame((long)(126 * 4)), // full packet d_done_sending(false), d_amplitude(16384) { if(verbose) std::cout << "[TEST_USRP_INBAND_TIMESTAMPS] Initializing...\n"; d_tx = define_port("tx0", "usrp-tx", false, mb_port::INTERNAL); d_rx = define_port("rx0", "usrp-rx", false, mb_port::INTERNAL); d_cs = define_port("cs", "usrp-server-cs", false, mb_port::INTERNAL); bool fake_usrp_p = false; // Test the TX side pmt_t usrp_dict = pmt_make_dict(); if(fake_usrp_p) { pmt_dict_set(usrp_dict, pmt_intern("fake-usrp"), PMT_T); } // Set TX and RX interpolations pmt_dict_set(usrp_dict, pmt_intern("interp-tx"), pmt_from_long(128)); pmt_dict_set(usrp_dict, pmt_intern("decim-rx"), pmt_from_long(16)); // Specify the RBF to use pmt_dict_set(usrp_dict, pmt_intern("rbf"), pmt_intern("tmac5.rbf")); define_component("server", "usrp_server", usrp_dict); connect("self", "tx0", "server", "tx0"); connect("self", "rx0", "server", "rx0"); connect("self", "cs", "server", "cs"); // initialize NCO double freq = 100e3; int interp = 32; // 32 -> 4MS/s double sample_rate = 128e6 / interp; d_nco.set_freq(2*M_PI * freq/sample_rate); } test_usrp_inband_timestamps::~test_usrp_inband_timestamps() { } void test_usrp_inband_timestamps::initial_transition() { open_usrp(); } void test_usrp_inband_timestamps::handle_message(mb_message_sptr msg) { pmt_t event = msg->signal(); pmt_t data = msg->data(); pmt_t port_id = msg->port_id(); pmt_t handle = PMT_F; pmt_t status = PMT_F; std::string error_msg; //std::cout << msg << std::endl; switch(d_state){ case OPENING_USRP: if (pmt_eq(event, s_response_open)){ status = pmt_nth(1, data); if (pmt_eq(status, PMT_T)){ allocate_channel(); return; } else { error_msg = "failed to open usrp:"; goto bail; } } goto unhandled; case ALLOCATING_CHANNEL: if (pmt_eq(event, s_response_allocate_channel)){ if(pmt_eq(d_tx->port_symbol(), port_id)) { status = pmt_nth(1, data); d_tx_chan = pmt_nth(2, data); if (pmt_eq(status, PMT_T)){ if(verbose) std::cout << "[TEST_USRP_INBAND_TIMESTAMPS] Received allocation for TX\n"; if(!pmt_eqv(d_rx_chan, PMT_NIL)) { enter_receiving(); enter_transmitting(); } return; } else { error_msg = "failed to allocate channel:"; goto bail; } } if(pmt_eq(d_rx->port_symbol(), port_id)) { status = pmt_nth(1, data); d_rx_chan = pmt_nth(2, data); if (pmt_eq(status, PMT_T)){ if(verbose) std::cout << "[TEST_USRP_INBAND_TIMESTAMPS] Received allocation for TX\n"; if(!pmt_eqv(d_tx_chan, PMT_NIL)) { enter_receiving(); enter_transmitting(); } return; } else { error_msg = "failed to allocate channel:"; goto bail; } } } goto unhandled; case TRANSMITTING: if (pmt_eq(event, s_response_xmit_raw_frame)){ handle = pmt_nth(0, data); status = pmt_nth(1, data); if (pmt_eq(status, PMT_T)){ handle_xmit_response(handle); return; } else { error_msg = "bad response-xmit-raw-frame:"; goto bail; } } if (pmt_eq(event, s_response_from_control_channel)) { std::cout << "ping response!\n"; } goto unhandled; case CLOSING_CHANNEL: if (pmt_eq(event, s_response_deallocate_channel)){ status = pmt_nth(1, data); if (pmt_eq(status, PMT_T)){ close_usrp(); return; } else { error_msg = "failed to deallocate channel:"; goto bail; } } goto unhandled; case CLOSING_USRP: if (pmt_eq(event, s_response_close)){ status = pmt_nth(1, data); if (pmt_eq(status, PMT_T)){ shutdown_all(PMT_T); return; } else { error_msg = "failed to close USRP:"; goto bail; } } goto unhandled; default: goto unhandled; } return; bail: std::cerr << error_msg << data << "status = " << status << std::endl; shutdown_all(PMT_F); return; unhandled: if(verbose && 0) std::cout << "test_usrp_inband_tx: unhandled msg: " << msg << "in state "<< d_state << std::endl; } void test_usrp_inband_timestamps::open_usrp() { pmt_t which_usrp = pmt_from_long(0); d_cs->send(s_cmd_open, pmt_list2(PMT_NIL, which_usrp)); d_state = OPENING_USRP; } void test_usrp_inband_timestamps::close_usrp() { d_cs->send(s_cmd_close, pmt_list1(PMT_NIL)); d_state = CLOSING_USRP; if(verbose) std::cout << "[TEST_USRP_INBAND_TIMESTAMPS] Closing USRP\n"; } void test_usrp_inband_timestamps::allocate_channel() { long capacity = (long) 16e6; d_tx->send(s_cmd_allocate_channel, pmt_list2(PMT_T, pmt_from_long(capacity))); d_rx->send(s_cmd_allocate_channel, pmt_list2(PMT_T, pmt_from_long(capacity))); d_state = ALLOCATING_CHANNEL; } void test_usrp_inband_timestamps::enter_receiving() { d_rx->send(s_cmd_start_recv_raw_samples, pmt_list2(PMT_F, d_rx_chan)); } void test_usrp_inband_timestamps::enter_transmitting() { d_state = TRANSMITTING; d_nsamples_xmitted = 0; if(verbose) std::cout << "[TEST_USRP_INBAND_TIMESTAMPS] Beginning transmission\n"; sleep(1); build_and_send_next_frame(); build_and_send_next_frame(); build_and_send_next_frame(); build_and_send_next_frame(); } void test_usrp_inband_timestamps::build_and_send_ping() { d_tx->send(s_cmd_to_control_channel, pmt_list2(PMT_NIL, pmt_list1(pmt_list2(s_op_ping_fixed, pmt_list2(pmt_from_long(0), pmt_from_long(0)))))); if(verbose && 0) std::cout << "[TEST_USRP_INBAND_TIMESTAMPS] Ping sent" << std::endl; } void test_usrp_inband_timestamps::build_and_send_next_frame() { // allocate the uniform vector for the samples // FIXME perhaps hold on to this between calls #if 0 long nsamples_this_frame = std::min(d_nsamples_to_send - d_nsamples_xmitted, d_samples_per_frame); #else long nsamples_this_frame = d_samples_per_frame; #endif if (nsamples_this_frame == 0){ d_done_sending = true; return; } size_t nshorts = 2 * nsamples_this_frame; // 16-bit I & Q pmt_t uvec = pmt_make_s16vector(nshorts, 0); size_t ignore; int16_t *samples = pmt_s16vector_writeable_elements(uvec, ignore); // fill in the complex sinusoid for (int i = 0; i < nsamples_this_frame; i++){ if (1){ gr_complex s; d_nco.sincos(&s, 1, d_amplitude); // write 16-bit i & q samples[2*i] = (int16_t) s.real(); samples[2*i+1] = (int16_t) s.imag(); } else { gr_complex s(d_amplitude, d_amplitude); // write 16-bit i & q samples[2*i] = (int16_t) s.real(); samples[2*i+1] = (int16_t) s.imag(); } } pmt_t timestamp; if(bskip) { timestamp = pmt_from_long(0x0); // throw away bcurr++; if(bcurr == bstep) { bskip = false; bcurr = 0; } } else { timestamp = pmt_from_long(0xffffffff); // NOW timestamp = pmt_from_long(ptime); ptime += incr; bcurr++; if(bcurr == bstep) { //bskip = true; bcurr = 0; } } std::cout << bskip << " -- " << bcurr << std::endl; d_tx->send(s_cmd_xmit_raw_frame, pmt_list4(pmt_from_long(d_nframes_xmitted), // invocation-handle d_tx_chan, // channel uvec, // the samples timestamp)); d_nsamples_xmitted += nsamples_this_frame; d_nframes_xmitted++; if(verbose && 0) std::cout << "[TEST_USRP_INBAND_TIMESTAMPS] Transmitted frame\n"; //build_and_send_next_frame(); } void test_usrp_inband_timestamps::handle_xmit_response(pmt_t handle) { if (d_done_sending && pmt_to_long(handle) == (d_nframes_xmitted - 1)){ // We're done sending and have received all responses enter_closing_channel(); } build_and_send_next_frame(); //build_and_send_ping(); } void test_usrp_inband_timestamps::enter_closing_channel() { d_state = CLOSING_CHANNEL; d_tx->send(s_cmd_deallocate_channel, pmt_list2(PMT_NIL, d_tx_chan)); if(verbose) std::cout << "[TEST_USRP_INBAND_TIMESTAMPS] Closing channel\n"; } REGISTER_MBLOCK_CLASS(test_usrp_inband_timestamps); // ---------------------------------------------------------------- int main (int argc, char **argv) { // handle any command line args here mb_runtime_sptr rt = mb_make_runtime(); pmt_t result = PMT_NIL; rt->run("top", "test_usrp_inband_timestamps", PMT_F, &result); }