// // Copyright 2010-2012 Ettus Research LLC // Copyright 2018 Ettus Research, a National Instruments Company // // SPDX-License-Identifier: GPL-3.0-or-later // #include "../../transport/super_recv_packet_handler.hpp" #include "../../transport/super_send_packet_handler.hpp" #include "fw_common.h" #include "usrp2_impl.hpp" #include "usrp2_regs.hpp" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include using namespace uhd; using namespace uhd::usrp; using namespace uhd::transport; namespace asio = boost::asio; namespace pt = boost::posix_time; /*********************************************************************** * helpers **********************************************************************/ static UHD_INLINE pt::time_duration to_time_dur(double timeout) { return pt::microseconds(long(timeout * 1e6)); } /*********************************************************************** * constants **********************************************************************/ static const size_t vrt_send_header_offset_words32 = 1; /*********************************************************************** * flow control monitor for a single tx channel * - the pirate thread calls update * - the get send buffer calls check **********************************************************************/ class flow_control_monitor { public: typedef uint32_t seq_type; typedef std::shared_ptr sptr; /*! * Make a new flow control monitor. * \param max_seqs_out num seqs before throttling */ flow_control_monitor(seq_type max_seqs_out) : _max_seqs_out(max_seqs_out) { this->clear(); _ready_fcn = std::bind(&flow_control_monitor::ready, this); } //! Clear the monitor, Ex: when a streamer is created void clear(void) { _last_seq_out = 0; _last_seq_ack = 0; } /*! * Gets the current sequence number to go out. * Increments the sequence for the next call * \return the sequence to be sent to the dsp */ UHD_INLINE seq_type get_curr_seq_out(void) { return _last_seq_out++; } /*! * Check the flow control condition. * \param timeout the timeout in seconds * \return false on timeout */ UHD_INLINE bool check_fc_condition(double timeout) { boost::mutex::scoped_lock lock(_fc_mutex); if (this->ready()) return true; boost::this_thread::disable_interruption di; // disable because the wait can throw return _fc_cond.timed_wait(lock, to_time_dur(timeout), _ready_fcn); } /*! * Update the flow control condition. * \param seq the last sequence number to be ACK'd */ UHD_INLINE void update_fc_condition(seq_type seq) { boost::mutex::scoped_lock lock(_fc_mutex); _last_seq_ack = seq; lock.unlock(); _fc_cond.notify_one(); } private: bool ready(void) { return seq_type(_last_seq_out - _last_seq_ack) < _max_seqs_out; } boost::mutex _fc_mutex; boost::condition _fc_cond; seq_type _last_seq_out, _last_seq_ack; const seq_type _max_seqs_out; std::function _ready_fcn; }; /*********************************************************************** * io impl details (internal to this file) * - pirate crew * - alignment buffer * - thread loop * - vrt packet handler states **********************************************************************/ struct usrp2_impl::io_impl { io_impl(void) : async_msg_fifo(1000 /*messages deep*/), tick_rate(1 /*non-zero default*/) { /* NOP */ } ~io_impl(void) { // Manually deconstuct the tasks, since this was not happening automatically. pirate_tasks.clear(); } managed_send_buffer::sptr get_send_buff(size_t chan, double timeout) { flow_control_monitor& fc_mon = *fc_mons[chan]; // wait on flow control w/ timeout if (not fc_mon.check_fc_condition(timeout)) return managed_send_buffer::sptr(); // get a buffer from the transport w/ timeout managed_send_buffer::sptr buff = tx_xports[chan]->get_send_buff(timeout); // write the flow control word into the buffer if (buff.get()) buff->cast()[0] = uhd::htonx(fc_mon.get_curr_seq_out()); return buff; } // tx dsp: xports and flow control monitors std::vector tx_xports; std::vector fc_mons; // methods and variables for the pirate crew void recv_pirate_loop(zero_copy_if::sptr, size_t, const std::atomic&); std::list pirate_tasks; bounded_buffer async_msg_fifo; double tick_rate; }; /*********************************************************************** * Receive Pirate Loop * - while raiding, loot for message packet * - update flow control condition count * - put async message packets into queue **********************************************************************/ void usrp2_impl::io_impl::recv_pirate_loop( zero_copy_if::sptr err_xport, size_t index, const std::atomic& exit_loop) { set_thread_priority_safe(); // store a reference to the flow control monitor (offset by max dsps) flow_control_monitor& fc_mon = *(this->fc_mons[index]); while (not exit_loop) { managed_recv_buffer::sptr buff = err_xport->get_recv_buff(); if (not buff.get()) continue; // ignore timeout/error buffers try { // extract the vrt header packet info vrt::if_packet_info_t if_packet_info; if_packet_info.num_packet_words32 = buff->size() / sizeof(uint32_t); const uint32_t* vrt_hdr = buff->cast(); vrt::if_hdr_unpack_be(vrt_hdr, if_packet_info); // handle a tx async report message if (if_packet_info.sid == USRP2_TX_ASYNC_SID and if_packet_info.packet_type != vrt::if_packet_info_t::PACKET_TYPE_DATA) { // fill in the async metadata async_metadata_t metadata; load_metadata_from_buff(uhd::ntohx, metadata, if_packet_info, vrt_hdr, tick_rate, index); // catch the flow control packets and react if (metadata.event_code == 0) { uint32_t fc_word32 = (vrt_hdr + if_packet_info.num_header_words32)[1]; fc_mon.update_fc_condition(uhd::ntohx(fc_word32)); continue; } // else UHD_LOGGER_DEBUG("USRP2") << "metadata.event_code " << // metadata.event_code; async_msg_fifo.push_with_pop_on_full(metadata); standard_async_msg_prints(metadata); } else { // TODO unknown received packet, may want to print error... } } catch (const std::exception& e) { UHD_LOGGER_ERROR("USRP2") << "Error in recv pirate loop: " << e.what(); } } } /*********************************************************************** * Helper Functions **********************************************************************/ void usrp2_impl::io_init(void) { // create new io impl _io_impl = UHD_PIMPL_MAKE(io_impl, ()); // init first so we dont have an access race for (const std::string& mb : _mbc.keys()) { // init the tx xport and flow control monitor _io_impl->tx_xports.push_back(_mbc[mb].tx_dsp_xport); _io_impl->fc_mons.push_back(flow_control_monitor::sptr( new flow_control_monitor(device_addr.cast("send_buff_size", USRP2_SRAM_BYTES) / _mbc[mb].tx_dsp_xport->get_send_frame_size()))); } // allocate streamer weak ptrs containers for (const std::string& mb : _mbc.keys()) { _mbc[mb].rx_streamers.resize(_mbc[mb].rx_dsps.size()); _mbc[mb].tx_streamers.resize(1 /*known to be 1 dsp*/); } // create a new pirate thread for each zc if (yarr!!) size_t index = 0; for (const std::string& mb : _mbc.keys()) { // spawn a new pirate to plunder the recv booty _io_impl->pirate_tasks.push_back( task::make(std::bind(&usrp2_impl::io_impl::recv_pirate_loop, _io_impl.get(), _mbc[mb].tx_dsp_xport, index++, std::ref(_pirate_task_exit)))); } } void usrp2_impl::update_tick_rate(const double rate) { _io_impl->tick_rate = rate; // shadow for async msg // update the tick rate on all existing streamers -> thread safe for (const std::string& mb : _mbc.keys()) { for (size_t i = 0; i < _mbc[mb].rx_streamers.size(); i++) { std::shared_ptr my_streamer = std::dynamic_pointer_cast( _mbc[mb].rx_streamers[i].lock()); if (my_streamer.get() == NULL) continue; my_streamer->set_tick_rate(rate); } for (size_t i = 0; i < _mbc[mb].tx_streamers.size(); i++) { std::shared_ptr my_streamer = std::dynamic_pointer_cast( _mbc[mb].tx_streamers[i].lock()); if (my_streamer.get() == NULL) continue; my_streamer->set_tick_rate(rate); } } } void usrp2_impl::update_rx_samp_rate( const std::string& mb, const size_t dsp, const double rate) { std::shared_ptr my_streamer = std::dynamic_pointer_cast( _mbc[mb].rx_streamers[dsp].lock()); if (my_streamer.get() == NULL) return; my_streamer->set_samp_rate(rate); const double adj = _mbc[mb].rx_dsps[dsp]->get_scaling_adjustment(); my_streamer->set_scale_factor(adj); } void usrp2_impl::update_tx_samp_rate( const std::string& mb, const size_t dsp, const double rate) { std::shared_ptr my_streamer = std::dynamic_pointer_cast( _mbc[mb].tx_streamers[dsp].lock()); if (my_streamer.get() == NULL) return; my_streamer->set_samp_rate(rate); const double adj = _mbc[mb].tx_dsp->get_scaling_adjustment(); my_streamer->set_scale_factor(adj); } void usrp2_impl::update_rates(void) { for (const std::string& mb : _mbc.keys()) { fs_path root = "/mboards/" + mb; _tree->access(root / "tick_rate").update(); // and now that the tick rate is set, init the host rates to something for (const std::string& name : _tree->list(root / "rx_dsps")) { _tree->access(root / "rx_dsps" / name / "rate" / "value").update(); } for (const std::string& name : _tree->list(root / "tx_dsps")) { _tree->access(root / "tx_dsps" / name / "rate" / "value").update(); } } } void usrp2_impl::update_rx_subdev_spec( const std::string& which_mb, const subdev_spec_t& spec) { fs_path root = "/mboards/" + which_mb + "/dboards"; // sanity checking validate_subdev_spec(_tree, spec, "rx", which_mb); // setup mux for this spec bool fe_swapped = false; for (size_t i = 0; i < spec.size(); i++) { const std::string conn = _tree ->access(root / spec[i].db_name / "rx_frontends" / spec[i].sd_name / "connection") .get(); if (i == 0 and (conn == "QI" or conn == "Q")) fe_swapped = true; _mbc[which_mb].rx_dsps[i]->set_mux(conn, fe_swapped); } _mbc[which_mb].rx_fe->set_mux(fe_swapped); // compute the new occupancy and resize _mbc[which_mb].rx_chan_occ = spec.size(); size_t nchan = 0; for (const std::string& mb : _mbc.keys()) nchan += _mbc[mb].rx_chan_occ; } void usrp2_impl::update_tx_subdev_spec( const std::string& which_mb, const subdev_spec_t& spec) { fs_path root = "/mboards/" + which_mb + "/dboards"; // sanity checking validate_subdev_spec(_tree, spec, "tx", which_mb); // set the mux for this spec const std::string conn = _tree ->access( root / spec[0].db_name / "tx_frontends" / spec[0].sd_name / "connection") .get(); _mbc[which_mb].tx_fe->set_mux(conn); // compute the new occupancy and resize _mbc[which_mb].tx_chan_occ = spec.size(); size_t nchan = 0; for (const std::string& mb : _mbc.keys()) nchan += _mbc[mb].tx_chan_occ; } /*********************************************************************** * Async Data **********************************************************************/ bool usrp2_impl::recv_async_msg(async_metadata_t& async_metadata, double timeout) { boost::this_thread::disable_interruption di; // disable because the wait can throw return _io_impl->async_msg_fifo.pop_with_timed_wait(async_metadata, timeout); } /*********************************************************************** * Stream destination programmer **********************************************************************/ void usrp2_impl::program_stream_dest( zero_copy_if::sptr& xport, const uhd::stream_args_t& args) { // perform an initial flush of transport while (xport->get_recv_buff(0.0)) { } // program the stream command usrp2_stream_ctrl_t stream_ctrl = usrp2_stream_ctrl_t(); stream_ctrl.sequence = uhd::htonx(uint32_t(0 /* don't care seq num */)); stream_ctrl.vrt_hdr = uhd::htonx(uint32_t(USRP2_INVALID_VRT_HEADER)); // user has provided an alternative address and port for destination if (args.args.has_key("addr") and args.args.has_key("port")) { UHD_LOGGER_INFO("USRP2") << boost::format("Programming streaming destination for custom address. " "IPv4 Address: %s, UDP Port: %s") % args.args["addr"] % args.args["port"]; asio::io_service io_service; asio::ip::udp::resolver resolver(io_service); asio::ip::udp::resolver::query query( asio::ip::udp::v4(), args.args["addr"], args.args["port"]); asio::ip::udp::endpoint endpoint = *resolver.resolve(query); stream_ctrl.ip_addr = uhd::htonx(uint32_t(endpoint.address().to_v4().to_ulong())); stream_ctrl.udp_port = uhd::htonx(uint32_t(endpoint.port())); for (size_t i = 0; i < 3; i++) { UHD_LOGGER_INFO("USRP2") << "ARP attempt " << i; managed_send_buffer::sptr send_buff = xport->get_send_buff(); std::memcpy(send_buff->cast(), &stream_ctrl, sizeof(stream_ctrl)); send_buff->commit(sizeof(stream_ctrl)); send_buff.reset(); std::this_thread::sleep_for(std::chrono::milliseconds(300)); managed_recv_buffer::sptr recv_buff = xport->get_recv_buff(0.0); if (recv_buff and recv_buff->size() >= sizeof(uint32_t)) { const uint32_t result = uhd::ntohx(recv_buff->cast()[0]); if (result == 0) { UHD_LOGGER_INFO("USRP2") << "Success! "; return; } } } throw uhd::runtime_error( "Device failed to ARP when programming alternative streaming destination."); } else { // send the partial stream control without destination managed_send_buffer::sptr send_buff = xport->get_send_buff(); std::memcpy(send_buff->cast(), &stream_ctrl, sizeof(stream_ctrl)); send_buff->commit(sizeof(stream_ctrl) / 2); } } /*********************************************************************** * Receive streamer **********************************************************************/ rx_streamer::sptr usrp2_impl::get_rx_stream(const uhd::stream_args_t& args_) { stream_args_t args = args_; // setup defaults for unspecified values args.otw_format = args.otw_format.empty() ? "sc16" : args.otw_format; args.channels = args.channels.empty() ? std::vector(1, 0) : args.channels; // calculate packet size static const size_t hdr_size = 0 + vrt::max_if_hdr_words32 * sizeof(uint32_t) + sizeof(vrt::if_packet_info_t().tlr) // forced to have trailer - sizeof(vrt::if_packet_info_t().cid) // no class id ever used - sizeof(vrt::if_packet_info_t().tsi) // no int time ever used ; const size_t bpp = _mbc[_mbc.keys().front()].rx_dsp_xports[0]->get_recv_frame_size() - hdr_size; const size_t bpi = convert::get_bytes_per_item(args.otw_format); const size_t spp = args.args.cast("spp", bpp / bpi); // make the new streamer given the samples per packet std::shared_ptr my_streamer = std::make_shared(spp); // init some streamer stuff my_streamer->resize(args.channels.size()); my_streamer->set_vrt_unpacker(&vrt::if_hdr_unpack_be); // set the converter uhd::convert::id_type id; id.input_format = args.otw_format + "_item32_be"; id.num_inputs = 1; id.output_format = args.cpu_format; id.num_outputs = 1; my_streamer->set_converter(id); // bind callbacks for the handler for (size_t chan_i = 0; chan_i < args.channels.size(); chan_i++) { const size_t chan = args.channels[chan_i]; size_t num_chan_so_far = 0; for (const std::string& mb : _mbc.keys()) { num_chan_so_far += _mbc[mb].rx_chan_occ; if (chan < num_chan_so_far) { const size_t dsp = chan + _mbc[mb].rx_chan_occ - num_chan_so_far; _mbc[mb].rx_dsps[dsp]->set_nsamps_per_packet( spp); // seems to be a good place to set this _mbc[mb].rx_dsps[dsp]->setup(args); this->program_stream_dest(_mbc[mb].rx_dsp_xports[dsp], args); my_streamer->set_xport_chan_get_buff(chan_i, std::bind(&zero_copy_if::get_recv_buff, _mbc[mb].rx_dsp_xports[dsp], std::placeholders::_1), true /*flush*/); my_streamer->set_issue_stream_cmd(chan_i, std::bind(&rx_dsp_core_200::issue_stream_command, _mbc[mb].rx_dsps[dsp], std::placeholders::_1)); _mbc[mb].rx_streamers[dsp] = my_streamer; // store weak pointer break; } } } // set the packet threshold to be an entire socket buffer's worth const size_t packets_per_sock_buff = size_t(50e6 / _mbc[_mbc.keys().front()].rx_dsp_xports[0]->get_recv_frame_size()); my_streamer->set_alignment_failure_threshold(packets_per_sock_buff); // sets all tick and samp rates on this streamer this->update_rates(); return my_streamer; } /*********************************************************************** * Transmit streamer **********************************************************************/ tx_streamer::sptr usrp2_impl::get_tx_stream(const uhd::stream_args_t& args_) { stream_args_t args = args_; // setup defaults for unspecified values args.otw_format = args.otw_format.empty() ? "sc16" : args.otw_format; args.channels = args.channels.empty() ? std::vector(1, 0) : args.channels; // calculate packet size static const size_t hdr_size = 0 + vrt_send_header_offset_words32 * sizeof(uint32_t) + vrt::max_if_hdr_words32 * sizeof(uint32_t) + sizeof(vrt::if_packet_info_t().tlr) // forced to have trailer - sizeof(vrt::if_packet_info_t().cid) // no class id ever used - sizeof(vrt::if_packet_info_t().sid) // no stream id ever used - sizeof(vrt::if_packet_info_t().tsi) // no int time ever used ; const size_t bpp = _mbc[_mbc.keys().front()].tx_dsp_xport->get_send_frame_size() - hdr_size; const size_t spp = bpp / convert::get_bytes_per_item(args.otw_format); // make the new streamer given the samples per packet std::shared_ptr my_streamer = std::make_shared(spp); // init some streamer stuff my_streamer->resize(args.channels.size()); my_streamer->set_vrt_packer(&vrt::if_hdr_pack_be, vrt_send_header_offset_words32); // set the converter uhd::convert::id_type id; id.input_format = args.cpu_format; id.num_inputs = 1; id.output_format = args.otw_format + "_item32_be"; id.num_outputs = 1; my_streamer->set_converter(id); // bind callbacks for the handler for (size_t chan_i = 0; chan_i < args.channels.size(); chan_i++) { const size_t chan = args.channels[chan_i]; size_t num_chan_so_far = 0; size_t abs = 0; for (const std::string& mb : _mbc.keys()) { num_chan_so_far += _mbc[mb].tx_chan_occ; if (chan < num_chan_so_far) { const size_t dsp = chan + _mbc[mb].tx_chan_occ - num_chan_so_far; if (not args.args.has_key("noclear")) { _io_impl->fc_mons[abs]->clear(); } _mbc[mb].tx_dsp->setup(args); my_streamer->set_xport_chan_get_buff(chan_i, std::bind(&usrp2_impl::io_impl::get_send_buff, _io_impl.get(), abs, std::placeholders::_1)); my_streamer->set_async_receiver( std::bind(&bounded_buffer::pop_with_timed_wait, &(_io_impl->async_msg_fifo), std::placeholders::_1, std::placeholders::_2)); _mbc[mb].tx_streamers[dsp] = my_streamer; // store weak pointer break; } abs += 1; // assume 1 tx dsp } } // sets all tick and samp rates on this streamer this->update_rates(); return my_streamer; }