// // Copyright 2019 Ettus Research, a National Instruments Brand // // SPDX-License-Identifier: GPL-3.0-or-later // #include "../common/mock_link.hpp" #include #include #include #include #include namespace uhd { namespace transport { /*! * Mock tx data xport which doesn't use I/O service, and just interacts with * the link directly. Transport copies packet info directly into the frame * buffer. */ class mock_tx_data_xport { public: using uptr = std::unique_ptr; using buff_t = uhd::transport::frame_buff; struct packet_info_t { bool eob = false; bool eov = false; bool has_tsf = false; uint64_t tsf = 0; size_t payload_bytes = 0; }; mock_tx_data_xport(mock_send_link::sptr send_link) : _send_link(send_link) {} buff_t::uptr get_send_buff(const int32_t timeout_ms) { return _send_link->get_send_buff(timeout_ms); } std::pair write_packet_header( buff_t::uptr& buff, const packet_info_t& info) { uint8_t* data = static_cast(buff->data()); *(reinterpret_cast(data)) = info; return std::make_pair(data + sizeof(info), sizeof(info) + info.payload_bytes); } void release_send_buff(buff_t::uptr buff) { _send_link->release_send_buff(std::move(buff)); } size_t get_mtu() const { return _send_link->get_send_frame_size(); } size_t get_chdr_hdr_len() const { return sizeof(packet_info_t); } size_t get_max_payload_size() const { return get_mtu() - get_chdr_hdr_len(); } private: mock_send_link::sptr _send_link; }; /*! * Mock tx streamer for testing */ class mock_tx_streamer : public tx_streamer_impl { public: mock_tx_streamer(const size_t num_chans, const uhd::stream_args_t& stream_args) : tx_streamer_impl(num_chans, stream_args) { } void set_tick_rate(double rate) { tx_streamer_impl::set_tick_rate(rate); } void set_samp_rate(double rate) { tx_streamer_impl::set_samp_rate(rate); } void set_scale_factor(const size_t chan, const double scale_factor) { tx_streamer_impl::set_scale_factor(chan, scale_factor); } bool recv_async_msg( uhd::async_metadata_t& /*async_metadata*/, double /*timeout = 0.1*/) override { return false; } }; }} // namespace uhd::transport using namespace uhd::transport; using tx_streamer = tx_streamer_impl; static const double TICK_RATE = 100e6; static const double SAMP_RATE = 10e6; static const size_t FRAME_SIZE = 1000; static const double SCALE_FACTOR = 2; /*! * Helper functions */ static std::vector make_links(const size_t num) { const mock_send_link::link_params params = {FRAME_SIZE, 1}; std::vector links; for (size_t i = 0; i < num; i++) { links.push_back(std::make_shared(params)); } return links; } static std::shared_ptr make_tx_streamer( std::vector send_links, const std::string& format) { const uhd::stream_args_t stream_args(format, "sc16"); auto streamer = std::make_shared(send_links.size(), stream_args); streamer->set_tick_rate(TICK_RATE); streamer->set_samp_rate(SAMP_RATE); for (size_t i = 0; i < send_links.size(); i++) { mock_tx_data_xport::uptr xport( std::make_unique(send_links[i])); streamer->set_scale_factor(i, SCALE_FACTOR); streamer->connect_channel(i, std::move(xport)); } return streamer; } std::tuple*, size_t, boost::shared_array> pop_send_packet(mock_send_link::sptr send_link) { auto packet = send_link->pop_send_packet(); const size_t packet_samps = (packet.second - sizeof(mock_tx_data_xport::packet_info_t)) / sizeof(std::complex); uint8_t* buff_ptr = packet.first.get(); auto info = *(reinterpret_cast(buff_ptr)); std::complex* data = reinterpret_cast*>( buff_ptr + sizeof(mock_tx_data_xport::packet_info_t)); return std::make_tuple(info, data, packet_samps, packet.first); } //! Generates a non-biased random number in the range (low, high). static size_t generate_rand(size_t low, size_t high) { return (std::rand() % (high - low + 1)) + low; } /*! * Generates a vector of legal random EOV positions. * `eovs` is a vector already sized to the desired number of EOV positions. * The range [1, num_samps) will be broken into N=`eov.size()` * non-overlapping adjacent ranges, and a random value within each range will * be generated and stored in the vector. */ static void generate_random_eov_positions( std::vector& eovs, const size_t num_samps) { UHD_ASSERT_THROW(!eovs.empty()); const size_t num_eovs = eovs.size(); const size_t range_size = (num_samps - 1) / num_eovs; size_t low = 1; for (size_t i = 0; i < num_eovs; i++) { const size_t high = low + range_size - 1; eovs[i] = generate_rand(low, high); low = high + 1; } } /*! * Tests */ BOOST_AUTO_TEST_CASE(test_send_one_channel_one_packet) { const size_t NUM_PKTS_TO_TEST = 30; const std::string format("fc32"); auto send_links = make_links(1); auto streamer = make_tx_streamer(send_links, format); // Allocate metadata uhd::tx_metadata_t metadata; metadata.has_time_spec = true; metadata.time_spec = uhd::time_spec_t(0.0); // Allocate buffer and write data std::vector> buff(20); for (size_t i = 0; i < buff.size(); i++) { buff[i] = std::complex(i * 2, i * 2 + 1); } // Send packets and check data size_t num_accum_samps = 0; for (size_t i = 0; i < NUM_PKTS_TO_TEST; i++) { std::cout << "sending packet " << i << std::endl; // Vary num_samps for each packet const size_t num_samps = 10 + i % 10; metadata.end_of_burst = (i == NUM_PKTS_TO_TEST - 1); const size_t num_sent = streamer->send(&buff.front(), num_samps, metadata, 1.0); BOOST_CHECK_EQUAL(num_sent, num_samps); metadata.time_spec += uhd::time_spec_t(0, num_sent, SAMP_RATE); mock_tx_data_xport::packet_info_t info; std::complex* data; size_t packet_samps; boost::shared_array frame_buff; std::tie(info, data, packet_samps, frame_buff) = pop_send_packet(send_links[0]); BOOST_CHECK_EQUAL(num_samps, packet_samps); // Check data for (size_t j = 0; j < num_samps; j++) { const std::complex value( (j * 2) * SCALE_FACTOR, (j * 2 + 1) * SCALE_FACTOR); BOOST_CHECK_EQUAL(value, data[j]); } BOOST_CHECK_EQUAL(num_samps, info.payload_bytes / sizeof(std::complex)); BOOST_CHECK(info.has_tsf); BOOST_CHECK_EQUAL(info.tsf, num_accum_samps * TICK_RATE / SAMP_RATE); BOOST_CHECK_EQUAL(info.eob, i == NUM_PKTS_TO_TEST - 1); num_accum_samps += num_samps; } } BOOST_AUTO_TEST_CASE(test_send_one_channel_eov_lte_spp) { const size_t NUM_PKTS_TO_TEST = 30; const std::string format("fc32"); auto send_links = make_links(1); auto streamer = make_tx_streamer(send_links, format); // Allocate metadata uhd::tx_metadata_t metadata; metadata.has_time_spec = true; metadata.time_spec = uhd::time_spec_t(0.0); // Allocate buffer const size_t num_samps = streamer->get_max_num_samps(); std::vector> buff(num_samps); // Send buffer and check resultant packets size_t num_accum_samps = 0; for (size_t i = 0; i < NUM_PKTS_TO_TEST; i++) { std::cout << "sending packet " << i << std::endl; // Vary number of EOVs for each send const size_t num_eovs = (i % 10) + 1; std::vector eovs(num_eovs); generate_random_eov_positions(eovs, num_samps); metadata.eov_positions = eovs.data(); metadata.eov_positions_size = eovs.size(); const size_t num_sent = streamer->send(&buff.front(), num_samps, metadata, 1.0); BOOST_CHECK_EQUAL(num_sent, num_samps); metadata.time_spec += uhd::time_spec_t(0, num_sent, SAMP_RATE); mock_tx_data_xport::packet_info_t info; std::complex* data; size_t packet_samps; boost::shared_array frame_buff; // Check number of packets written (should be # of EOVs plus one) size_t num_packets_written = send_links[0]->get_num_packets(); BOOST_CHECK_EQUAL(num_packets_written, eovs.size() + 1); // Pop each packets and check size of each relative to EOV positions size_t total_samps_popped = 0; size_t eov_index = 0; size_t last_eov_position = 0; while (total_samps_popped < num_samps) { std::tie(info, data, packet_samps, frame_buff) = pop_send_packet(send_links[0]); // All but the last packet should have an EOV indication if (eov_index < eovs.size()) { BOOST_CHECK_EQUAL(eovs[eov_index] - last_eov_position, packet_samps); BOOST_CHECK(info.eov); last_eov_position = eovs[eov_index]; } else { BOOST_CHECK_EQUAL(num_samps - last_eov_position, packet_samps); BOOST_CHECK(not info.eov); } // Verify correctness of TSF data BOOST_CHECK(info.has_tsf); BOOST_CHECK_EQUAL(info.tsf, num_accum_samps * TICK_RATE / SAMP_RATE); eov_index++; num_accum_samps += packet_samps; total_samps_popped += packet_samps; } } } BOOST_AUTO_TEST_CASE(test_send_one_channel_eov_gt_spp) { const size_t NUM_PKTS_TO_TEST = 30; const std::string format("fc32"); auto send_links = make_links(1); auto streamer = make_tx_streamer(send_links, format); // Allocate metadata uhd::tx_metadata_t metadata; metadata.has_time_spec = true; metadata.time_spec = uhd::time_spec_t(0.0); // Allocate buffer const size_t spp = streamer->get_max_num_samps(); const size_t num_samps = spp * 50; std::vector> buff(num_samps); // Send buffer and check resultant packets size_t num_accum_samps = 0; for (size_t i = 0; i < NUM_PKTS_TO_TEST; i++) { std::cout << "sending packet " << i << std::endl; // Vary number of EOVs for each send const size_t num_eovs = (i % 5) + 1; std::vector eovs(num_eovs); generate_random_eov_positions(eovs, num_samps); metadata.eov_positions = eovs.data(); metadata.eov_positions_size = eovs.size(); const size_t num_sent = streamer->send(&buff.front(), num_samps, metadata, 1.0); BOOST_CHECK_EQUAL(num_sent, num_samps); metadata.time_spec += uhd::time_spec_t(0, num_sent, SAMP_RATE); mock_tx_data_xport::packet_info_t info; std::complex* data; size_t packet_samps; boost::shared_array frame_buff; size_t total_samps_popped = 0; size_t eov_index = 0; size_t last_eov_position = 0; size_t distance_to_next_eov = eovs[eov_index] - last_eov_position; size_t distance_to_end = num_samps; while (total_samps_popped < num_samps) { std::tie(info, data, packet_samps, frame_buff) = pop_send_packet(send_links[0]); if (distance_to_next_eov <= spp) { // Next EOV is within a single SPP: ensure packet is EOV BOOST_CHECK_EQUAL(distance_to_next_eov, packet_samps); BOOST_CHECK(info.eov); last_eov_position = eovs[eov_index]; eov_index++; if (eov_index < eovs.size()) { // NOTE: Addition of `packet_samps` is to compensate for // its subtraction below distance_to_next_eov = eovs[eov_index] - last_eov_position + packet_samps; } else { // No more EOVs distance_to_next_eov = std::numeric_limits::max(); } } else if (distance_to_end <= spp) { // End of data within a single SPP BOOST_CHECK_EQUAL(distance_to_end, packet_samps); BOOST_CHECK(not info.eov); } else { BOOST_CHECK(not info.eov); } // Verify correctness of TSF data BOOST_CHECK(info.has_tsf); BOOST_CHECK_EQUAL(info.tsf, num_accum_samps * TICK_RATE / SAMP_RATE); distance_to_end -= packet_samps; distance_to_next_eov -= packet_samps; total_samps_popped += packet_samps; num_accum_samps += packet_samps; } } } BOOST_AUTO_TEST_CASE(test_send_one_channel_eov_corner_case) { const std::string format("fc32"); auto send_links = make_links(1); auto streamer = make_tx_streamer(send_links, format); // Allocate metadata uhd::tx_metadata_t metadata; metadata.has_time_spec = true; metadata.time_spec = uhd::time_spec_t(0.0); // Allocate buffer const size_t spp = streamer->get_max_num_samps(); const size_t num_samps = spp * 2; std::vector> buff(num_samps); // Mark every sample as an EOV :D std::vector eovs(num_samps); for (size_t i = 0; i < num_samps; i++) { eovs[i] = i + 1; } metadata.eov_positions = eovs.data(); metadata.eov_positions_size = eovs.size(); const size_t num_sent = streamer->send(&buff.front(), num_samps, metadata, 1.0); BOOST_CHECK_EQUAL(num_sent, num_samps); mock_tx_data_xport::packet_info_t info; std::complex* data; size_t packet_samps; boost::shared_array frame_buff; // Check all packets for EOV BOOST_CHECK_EQUAL(send_links[0]->get_num_packets(), num_samps); for (size_t i = 0; i < num_samps; i++) { std::tie(info, data, packet_samps, frame_buff) = pop_send_packet(send_links[0]); BOOST_CHECK_EQUAL(packet_samps, 1); BOOST_CHECK(info.eov); } } BOOST_AUTO_TEST_CASE(test_send_one_channel_eov_error_cases) { const std::string format("fc32"); auto send_links = make_links(1); auto streamer = make_tx_streamer(send_links, format); uhd::tx_metadata_t metadata; metadata.has_time_spec = true; metadata.time_spec = uhd::time_spec_t(0.0); const size_t spp = streamer->get_max_num_samps(); const size_t num_samps = spp; std::vector> buff(num_samps); // Error case: EOV of 0 size_t eov = 0; metadata.eov_positions = &eov; metadata.eov_positions_size = 1; BOOST_CHECK_THROW( streamer->send(&buff.front(), num_samps, metadata, 1.0), uhd::value_error); // Error case: Adjacent EOV values that are the same std::vector eovs{100, 100}; metadata.eov_positions = eovs.data(); metadata.eov_positions_size = eovs.size(); BOOST_CHECK_THROW( streamer->send(&buff.front(), num_samps, metadata, 1.0), uhd::value_error); // Error case: EOV values not monotonically increasing eovs = {50, 25}; BOOST_CHECK_THROW( streamer->send(&buff.front(), num_samps, metadata, 1.0), uhd::value_error); // Error case: EOV values greater than nsamps_per_buff BOOST_CHECK_THROW(streamer->send(&buff.front(), 1, metadata, 1.0), uhd::value_error); } BOOST_AUTO_TEST_CASE(test_send_one_channel_multi_packet) { const size_t NUM_BUFFS_TO_TEST = 5; const std::string format("fc64"); auto send_links = make_links(1); auto streamer = make_tx_streamer(send_links, format); // Allocate metadata uhd::tx_metadata_t metadata; metadata.has_time_spec = true; metadata.time_spec = uhd::time_spec_t(0.0); // Allocate buffer and write data const size_t spp = streamer->get_max_num_samps(); const size_t num_samps = spp * 4; std::vector> buff(num_samps); for (size_t i = 0; i < buff.size(); i++) { buff[i] = std::complex(i * 2, i * 2 + 1); } // Send packets and check data size_t num_accum_samps = 0; for (size_t i = 0; i < NUM_BUFFS_TO_TEST; i++) { std::cout << "sending packet " << i << std::endl; metadata.end_of_burst = true; const size_t num_sent = streamer->send(&buff.front(), num_samps, metadata, 1.0); BOOST_CHECK_EQUAL(num_sent, num_samps); metadata.time_spec += uhd::time_spec_t(0, num_sent, SAMP_RATE); size_t samps_checked = 0; while (samps_checked < num_samps) { mock_tx_data_xport::packet_info_t info; std::complex* data; size_t packet_samps; boost::shared_array frame_buff; std::tie(info, data, packet_samps, frame_buff) = pop_send_packet(send_links[0]); for (size_t j = 0; j < packet_samps; j++) { const size_t n = j + samps_checked; const std::complex value( (n * 2) * SCALE_FACTOR, (n * 2 + 1) * SCALE_FACTOR); BOOST_CHECK_EQUAL(value, data[j]); } BOOST_CHECK_EQUAL( packet_samps, info.payload_bytes / sizeof(std::complex)); BOOST_CHECK(info.has_tsf); BOOST_CHECK_EQUAL( info.tsf, (num_accum_samps + samps_checked) * TICK_RATE / SAMP_RATE); samps_checked += packet_samps; BOOST_CHECK_EQUAL(info.eob, samps_checked == num_samps); } BOOST_CHECK_EQUAL(samps_checked, num_samps); num_accum_samps += samps_checked; } } BOOST_AUTO_TEST_CASE(test_send_two_channel_one_packet) { const size_t NUM_PKTS_TO_TEST = 30; const std::string format("sc16"); auto send_links = make_links(2); auto streamer = make_tx_streamer(send_links, format); // Allocate metadata uhd::tx_metadata_t metadata; metadata.has_time_spec = true; metadata.time_spec = uhd::time_spec_t(0.0); // Allocate buffer and write data std::vector> buff(20); for (size_t i = 0; i < buff.size(); i++) { buff[i] = std::complex(i * 2, i * 2 + 1); } std::vector buffs; for (size_t ch = 0; ch < 2; ch++) { buffs.push_back(buff.data()); // same buffer for each channel } // Send packets and check data size_t num_accum_samps = 0; for (size_t i = 0; i < NUM_PKTS_TO_TEST; i++) { std::cout << "sending packet " << i << std::endl; // Vary num_samps for each packet const size_t num_samps = 10 + i % 10; metadata.end_of_burst = (i == NUM_PKTS_TO_TEST - 1); const size_t num_sent = streamer->send(buffs, num_samps, metadata, 1.0); BOOST_CHECK_EQUAL(num_sent, num_samps); metadata.time_spec += uhd::time_spec_t(0, num_sent, SAMP_RATE); for (size_t ch = 0; ch < 2; ch++) { mock_tx_data_xport::packet_info_t info; std::complex* data; size_t packet_samps; boost::shared_array frame_buff; std::tie(info, data, packet_samps, frame_buff) = pop_send_packet(send_links[ch]); BOOST_CHECK_EQUAL(num_samps, packet_samps); // Check data for (size_t j = 0; j < num_samps; j++) { const std::complex value((j * 2), (j * 2 + 1)); BOOST_CHECK_EQUAL(value, data[j]); } BOOST_CHECK_EQUAL( num_samps, info.payload_bytes / sizeof(std::complex)); BOOST_CHECK(info.has_tsf); BOOST_CHECK_EQUAL(info.tsf, num_accum_samps * TICK_RATE / SAMP_RATE); BOOST_CHECK_EQUAL(info.eob, i == NUM_PKTS_TO_TEST - 1); } num_accum_samps += num_samps; } } BOOST_AUTO_TEST_CASE(test_meta_data_cache) { auto send_links = make_links(1); auto streamer = make_tx_streamer(send_links, "fc32"); // Allocate metadata uhd::tx_metadata_t metadata; metadata.start_of_burst = true; metadata.end_of_burst = true; metadata.has_time_spec = true; metadata.time_spec = uhd::time_spec_t(0.0); // Allocate buffer and write data std::vector> buff(20); size_t num_sent = streamer->send(buff.data(), 0, metadata, 1.0); BOOST_CHECK_EQUAL(send_links[0]->get_num_packets(), 0); BOOST_CHECK_EQUAL(num_sent, 0); uhd::tx_metadata_t metadata2; num_sent = streamer->send(buff.data(), 10, metadata2, 1.0); mock_tx_data_xport::packet_info_t info; size_t packet_samps; boost::shared_array frame_buff; std::tie(info, std::ignore, packet_samps, frame_buff) = pop_send_packet(send_links[0]); BOOST_CHECK_EQUAL(packet_samps, num_sent); BOOST_CHECK(info.has_tsf); BOOST_CHECK(info.eob); } BOOST_AUTO_TEST_CASE(test_spp) { // Test the spp calculation when it is limited by the stream args { auto send_links = make_links(1); uhd::stream_args_t stream_args("fc64", "sc16"); stream_args.args["spp"] = std::to_string(10); auto streamer = std::make_shared(send_links.size(), stream_args); mock_tx_data_xport::uptr xport( std::make_unique(send_links[0])); streamer->connect_channel(0, std::move(xport)); BOOST_CHECK_EQUAL(streamer->get_max_num_samps(), 10); } // Test the spp calculation when it is limited by the frame size { auto send_links = make_links(1); uhd::stream_args_t stream_args("fc64", "sc16"); stream_args.args["spp"] = std::to_string(10000); auto streamer = std::make_shared(send_links.size(), stream_args); mock_tx_data_xport::uptr xport( std::make_unique(send_links[0])); const size_t max_pyld = xport->get_max_payload_size(); streamer->connect_channel(0, std::move(xport)); BOOST_CHECK_EQUAL( streamer->get_max_num_samps(), max_pyld / sizeof(std::complex)); } }