// // Copyright 2010-2012 Ettus Research LLC // // This program 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 of the License, or // (at your option) any later version. // // This program 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, see . // #include "validate_subdev_spec.hpp" #define SRPH_DONT_CHECK_SEQUENCE #include "../../transport/super_recv_packet_handler.hpp" #define SSPH_DONT_PAD_TO_ONE #include "../../transport/super_send_packet_handler.hpp" #include "usrp1_calc_mux.hpp" #include "usrp1_impl.hpp" #include #include #include #include #include #include #include #include #include #include #define bmFR_RX_FORMAT_SHIFT_SHIFT 0 #define bmFR_RX_FORMAT_WIDTH_SHIFT 4 #define bmFR_TX_FORMAT_16_IQ 0 #define bmFR_RX_FORMAT_WANT_Q (0x1 << 9) #define FR_RX_FREQ_0 34 #define FR_RX_FREQ_1 35 #define FR_RX_FREQ_2 36 #define FR_RX_FREQ_3 37 #define FR_INTERP_RATE 32 #define FR_DECIM_RATE 33 #define FR_RX_MUX 38 #define FR_TX_MUX 39 #define FR_TX_FORMAT 48 #define FR_RX_FORMAT 49 #define FR_TX_SAMPLE_RATE_DIV 0 #define FR_RX_SAMPLE_RATE_DIV 1 #define GS_TX_UNDERRUN 0 #define GS_RX_OVERRUN 1 #define VRQ_GET_STATUS 0x80 using namespace uhd; using namespace uhd::usrp; using namespace uhd::transport; static const size_t alignment_padding = 512; /*********************************************************************** * Helper struct to associate an offset with a buffer **********************************************************************/ struct offset_send_buffer{ offset_send_buffer(void){ /* NOP */ } offset_send_buffer(managed_send_buffer::sptr buff, size_t offset = 0): buff(buff), offset(offset) { /* NOP */ } //member variables managed_send_buffer::sptr buff; size_t offset; /* in bytes */ }; /*********************************************************************** * Reusable managed send buffer to handle aligned commits **********************************************************************/ class offset_managed_send_buffer : public managed_send_buffer{ public: typedef boost::function commit_cb_type; offset_managed_send_buffer(const commit_cb_type &commit_cb): _commit_cb(commit_cb) { /* NOP */ } void commit(size_t size){ if (size != 0) this->_commit_cb(_curr_buff, _next_buff, size); } sptr get_new( offset_send_buffer &curr_buff, offset_send_buffer &next_buff ){ _curr_buff = curr_buff; _next_buff = next_buff; return make_managed_buffer(this); } private: void *get_buff(void) const{return _curr_buff.buff->cast() + _curr_buff.offset;} size_t get_size(void) const{return _curr_buff.buff->size() - _curr_buff.offset;} offset_send_buffer _curr_buff, _next_buff; commit_cb_type _commit_cb; }; /*********************************************************************** * BS VRT packer/unpacker functions (since samples don't have headers) **********************************************************************/ static void usrp1_bs_vrt_packer( boost::uint32_t *, vrt::if_packet_info_t &if_packet_info ){ if_packet_info.num_header_words32 = 0; if_packet_info.num_packet_words32 = if_packet_info.num_payload_words32; } static void usrp1_bs_vrt_unpacker( const boost::uint32_t *, vrt::if_packet_info_t &if_packet_info ){ if_packet_info.packet_type = vrt::if_packet_info_t::PACKET_TYPE_DATA; if_packet_info.num_payload_words32 = if_packet_info.num_packet_words32; if_packet_info.num_payload_bytes = if_packet_info.num_packet_words32*sizeof(boost::uint32_t); if_packet_info.num_header_words32 = 0; if_packet_info.packet_count = 0; if_packet_info.sob = false; if_packet_info.eob = false; if_packet_info.has_sid = false; if_packet_info.has_cid = false; if_packet_info.has_tsi = false; if_packet_info.has_tsf = false; if_packet_info.has_tlr = false; } /*********************************************************************** * IO Implementation Details **********************************************************************/ struct usrp1_impl::io_impl{ io_impl(zero_copy_if::sptr data_transport): data_transport(data_transport), curr_buff(offset_send_buffer(data_transport->get_send_buff())), omsb(boost::bind(&usrp1_impl::io_impl::commit_send_buff, this, _1, _2, _3)) { /* NOP */ } ~io_impl(void){ UHD_SAFE_CALL(flush_send_buff();) } zero_copy_if::sptr data_transport; //wrapper around the actual send buffer interface //all of this to ensure only aligned lengths are committed //NOTE: you must commit before getting a new buffer //since the vrt packet handler obeys this, we are ok offset_send_buffer curr_buff; offset_managed_send_buffer omsb; void commit_send_buff(offset_send_buffer&, offset_send_buffer&, size_t); void flush_send_buff(void); managed_send_buffer::sptr get_send_buff(double timeout){ //try to get a new managed buffer with timeout offset_send_buffer next_buff(data_transport->get_send_buff(timeout)); if (not next_buff.buff.get()) return managed_send_buffer::sptr(); /* propagate timeout here */ //make a new managed buffer with the offset buffs return omsb.get_new(curr_buff, next_buff); } task::sptr vandal_task; boost::system_time last_send_time; }; /*! * Perform an actual commit on the send buffer: * Copy the remainder of alignment to the next buffer. * Commit the current buffer at multiples of alignment. */ void usrp1_impl::io_impl::commit_send_buff( offset_send_buffer &curr, offset_send_buffer &next, size_t num_bytes ){ //total number of bytes now in the current buffer size_t bytes_in_curr_buffer = curr.offset + num_bytes; //calculate how many to commit and remainder size_t num_bytes_remaining = bytes_in_curr_buffer % alignment_padding; size_t num_bytes_to_commit = bytes_in_curr_buffer - num_bytes_remaining; //copy the remainder into the next buffer std::memcpy( next.buff->cast() + next.offset, curr.buff->cast() + num_bytes_to_commit, num_bytes_remaining ); //update the offset into the next buffer next.offset += num_bytes_remaining; //commit the current buffer curr.buff->commit(num_bytes_to_commit); //store the next buffer for the next call curr_buff = next; } /*! * Flush the current buffer by padding out to alignment and committing. */ void usrp1_impl::io_impl::flush_send_buff(void){ //calculate the number of bytes to alignment size_t bytes_to_pad = (-1*curr_buff.offset)%alignment_padding; //send at least alignment_padding to guarantee zeros are sent if (bytes_to_pad == 0) bytes_to_pad = alignment_padding; //get the buffer, clear, and commit (really current buffer) managed_send_buffer::sptr buff = this->get_send_buff(.1); if (buff.get() != NULL){ std::memset(buff->cast(), 0, bytes_to_pad); buff->commit(bytes_to_pad); } } /*********************************************************************** * Initialize internals within this file **********************************************************************/ void usrp1_impl::io_init(void){ _io_impl = UHD_PIMPL_MAKE(io_impl, (_data_transport)); //init as disabled, then call the real function (uses restore) this->enable_rx(false); this->enable_tx(false); rx_stream_on_off(false); tx_stream_on_off(false); _io_impl->flush_send_buff(); //create a new vandal thread to poll xerflow conditions _io_impl->vandal_task = task::make(boost::bind( &usrp1_impl::vandal_conquest_loop, this )); } void usrp1_impl::rx_stream_on_off(bool enb){ this->restore_rx(enb); //drain any junk in the receive transport after stop streaming command while(not enb and _data_transport->get_recv_buff().get() != NULL){ /* NOP */ } } void usrp1_impl::tx_stream_on_off(bool enb){ _io_impl->last_send_time = boost::get_system_time(); if (_tx_enabled and not enb) _io_impl->flush_send_buff(); this->restore_tx(enb); } /*! * Casually poll the overflow and underflow registers. * On an underflow, push an async message into the queue and print. * On an overflow, interleave an inline message into recv and print. * This procedure creates "soft" inline and async user messages. */ void usrp1_impl::vandal_conquest_loop(void){ //initialize the async metadata async_metadata_t async_metadata; async_metadata.channel = 0; async_metadata.has_time_spec = true; async_metadata.event_code = async_metadata_t::EVENT_CODE_UNDERFLOW; //initialize the inline metadata rx_metadata_t inline_metadata; inline_metadata.has_time_spec = true; inline_metadata.error_code = rx_metadata_t::ERROR_CODE_OVERFLOW; //start the polling loop... try{ while (not boost::this_thread::interruption_requested()){ boost::uint8_t underflow = 0, overflow = 0; //shutoff transmit if it has been too long since send() was called if (_tx_enabled and (boost::get_system_time() - _io_impl->last_send_time) > boost::posix_time::milliseconds(100)){ this->tx_stream_on_off(false); } //always poll regardless of enabled so we can clear the conditions _fx2_ctrl->usrp_control_read( VRQ_GET_STATUS, 0, GS_TX_UNDERRUN, &underflow, sizeof(underflow) ); _fx2_ctrl->usrp_control_read( VRQ_GET_STATUS, 0, GS_RX_OVERRUN, &overflow, sizeof(overflow) ); //handle message generation for xerflow conditions if (_tx_enabled and underflow){ async_metadata.time_spec = _soft_time_ctrl->get_time(); _soft_time_ctrl->get_async_queue().push_with_pop_on_full(async_metadata); UHD_MSG(fastpath) << "U"; } if (_rx_enabled and overflow){ inline_metadata.time_spec = _soft_time_ctrl->get_time(); _soft_time_ctrl->get_inline_queue().push_with_pop_on_full(inline_metadata); UHD_MSG(fastpath) << "O"; } boost::this_thread::sleep(boost::posix_time::milliseconds(50)); }} catch(const boost::thread_interrupted &){} //normal exit condition catch(const std::exception &e){ UHD_MSG(error) << "The vandal caught an unexpected exception " << e.what() << std::endl; } } /*********************************************************************** * RX streamer wrapper that talks to soft time control **********************************************************************/ class usrp1_recv_packet_streamer : public sph::recv_packet_handler, public rx_streamer{ public: usrp1_recv_packet_streamer(const size_t max_num_samps, soft_time_ctrl::sptr stc){ _max_num_samps = max_num_samps; _stc = stc; } size_t get_num_channels(void) const{ return this->size(); } size_t get_max_num_samps(void) const{ return _max_num_samps; } size_t recv( const rx_streamer::buffs_type &buffs, const size_t nsamps_per_buff, uhd::rx_metadata_t &metadata, const double timeout, const bool one_packet ){ //interleave a "soft" inline message into the receive stream: if (_stc->get_inline_queue().pop_with_haste(metadata)) return 0; size_t num_samps_recvd = sph::recv_packet_handler::recv( buffs, nsamps_per_buff, metadata, timeout, one_packet ); return _stc->recv_post(metadata, num_samps_recvd); } private: size_t _max_num_samps; soft_time_ctrl::sptr _stc; }; /*********************************************************************** * TX streamer wrapper that talks to soft time control **********************************************************************/ class usrp1_send_packet_streamer : public sph::send_packet_handler, public tx_streamer{ public: usrp1_send_packet_streamer(const size_t max_num_samps, soft_time_ctrl::sptr stc, boost::function tx_enb_fcn){ _max_num_samps = max_num_samps; this->set_max_samples_per_packet(_max_num_samps); _stc = stc; _tx_enb_fcn = tx_enb_fcn; } size_t get_num_channels(void) const{ return this->size(); } size_t get_max_num_samps(void) const{ return _max_num_samps; } size_t send( const tx_streamer::buffs_type &buffs, const size_t nsamps_per_buff, const uhd::tx_metadata_t &metadata, const double timeout_ ){ double timeout = timeout_; //rw copy _stc->send_pre(metadata, timeout); _tx_enb_fcn(true); //always enable (it will do the right thing) size_t num_samps_sent = sph::send_packet_handler::send( buffs, nsamps_per_buff, metadata, timeout ); //handle eob flag (commit the buffer, //disable the DACs) //check num samps sent to avoid flush on incomplete/timeout if (metadata.end_of_burst and num_samps_sent == nsamps_per_buff){ async_metadata_t metadata; metadata.channel = 0; metadata.has_time_spec = true; metadata.time_spec = _stc->get_time(); metadata.event_code = async_metadata_t::EVENT_CODE_BURST_ACK; _stc->get_async_queue().push_with_pop_on_full(metadata); _tx_enb_fcn(false); } return num_samps_sent; } private: size_t _max_num_samps; soft_time_ctrl::sptr _stc; boost::function _tx_enb_fcn; }; /*********************************************************************** * Properties callback methods below **********************************************************************/ void usrp1_impl::update_rx_subdev_spec(const uhd::usrp::subdev_spec_t &spec){ //sanity checking validate_subdev_spec(_tree, spec, "rx"); _rx_subdev_spec = spec; //shadow //set the mux and set the number of rx channels std::vector mapping; BOOST_FOREACH(const subdev_spec_pair_t &pair, spec){ const std::string conn = _tree->access(str(boost::format( "/mboards/0/dboards/%s/rx_frontends/%s/connection" ) % pair.db_name % pair.sd_name)).get(); mapping.push_back(std::make_pair(pair.db_name, conn)); } bool s = this->disable_rx(); _iface->poke32(FR_RX_MUX, calc_rx_mux(mapping)); this->restore_rx(s); } void usrp1_impl::update_tx_subdev_spec(const uhd::usrp::subdev_spec_t &spec){ //sanity checking validate_subdev_spec(_tree, spec, "tx"); _tx_subdev_spec = spec; //shadow //set the mux and set the number of tx channels std::vector mapping; BOOST_FOREACH(const subdev_spec_pair_t &pair, spec){ const std::string conn = _tree->access(str(boost::format( "/mboards/0/dboards/%s/tx_frontends/%s/connection" ) % pair.db_name % pair.sd_name)).get(); mapping.push_back(std::make_pair(pair.db_name, conn)); } bool s = this->disable_tx(); _iface->poke32(FR_TX_MUX, calc_tx_mux(mapping)); this->restore_tx(s); } void usrp1_impl::update_tick_rate(const double rate){ //updating this variable should: //update dboard iface -> it has a reference //update dsp freq bounds -> publisher _master_clock_rate = rate; } uhd::meta_range_t usrp1_impl::get_rx_dsp_host_rates(void){ meta_range_t range; const size_t div = this->has_rx_halfband()? 2 : 1; for (int rate = 256; rate >= 4; rate -= div){ range.push_back(range_t(_master_clock_rate/rate)); } return range; } uhd::meta_range_t usrp1_impl::get_tx_dsp_host_rates(void){ meta_range_t range; const size_t div = this->has_tx_halfband()? 2 : 1; for (int rate = 256; rate >= 8; rate -= div){ range.push_back(range_t(_master_clock_rate/rate)); } return range; } double usrp1_impl::update_rx_samp_rate(size_t dspno, const double samp_rate){ const size_t div = this->has_rx_halfband()? 2 : 1; const size_t rate = boost::math::iround(_master_clock_rate/this->get_rx_dsp_host_rates().clip(samp_rate, true)); if (rate < 8 and this->has_rx_halfband()) UHD_MSG(warning) << "USRP1 cannot achieve decimations below 8 when the half-band filter is present.\n" "The usrp1_fpga_4rx.rbf file is a special FPGA image without RX half-band filters.\n" "To load this image, set the device address key/value pair: fpga=usrp1_fpga_4rx.rbf\n" << std::endl; if (dspno == 0){ //only care if dsp0 is set since its homogeneous bool s = this->disable_rx(); _iface->poke32(FR_RX_SAMPLE_RATE_DIV, div - 1); _iface->poke32(FR_DECIM_RATE, rate/div - 1); this->restore_rx(s); //update the streamer if created boost::shared_ptr my_streamer = boost::dynamic_pointer_cast(_rx_streamer.lock()); if (my_streamer.get() != NULL){ my_streamer->set_samp_rate(_master_clock_rate / rate); } } return _master_clock_rate / rate; } double usrp1_impl::update_tx_samp_rate(size_t dspno, const double samp_rate){ const size_t div = this->has_tx_halfband()? 4 : 2; //doubled for codec interp const size_t rate = boost::math::iround(_master_clock_rate/this->get_tx_dsp_host_rates().clip(samp_rate, true)); if (dspno == 0){ //only care if dsp0 is set since its homogeneous bool s = this->disable_tx(); _iface->poke32(FR_TX_SAMPLE_RATE_DIV, div - 1); _iface->poke32(FR_INTERP_RATE, rate/div - 1); this->restore_tx(s); //update the streamer if created boost::shared_ptr my_streamer = boost::dynamic_pointer_cast(_tx_streamer.lock()); if (my_streamer.get() != NULL){ my_streamer->set_samp_rate(_master_clock_rate / rate); } } return _master_clock_rate / rate; } void usrp1_impl::update_rates(void){ const fs_path mb_path = "/mboards/0"; this->update_tick_rate(_master_clock_rate); BOOST_FOREACH(const std::string &name, _tree->list(mb_path / "rx_dsps")){ _tree->access(mb_path / "rx_dsps" / name / "rate" / "value").update(); } BOOST_FOREACH(const std::string &name, _tree->list(mb_path / "tx_dsps")){ _tree->access(mb_path / "tx_dsps" / name / "rate" / "value").update(); } } double usrp1_impl::update_rx_dsp_freq(const size_t dspno, const double freq_){ //correct for outside of rate (wrap around) double freq = std::fmod(freq_, _master_clock_rate); if (std::abs(freq) > _master_clock_rate/2.0) freq -= boost::math::sign(freq)*_master_clock_rate; //calculate the freq register word (signed) UHD_ASSERT_THROW(std::abs(freq) <= _master_clock_rate/2.0); static const double scale_factor = std::pow(2.0, 32); const boost::int32_t freq_word = boost::int32_t(boost::math::round((freq / _master_clock_rate) * scale_factor)); static const boost::uint32_t dsp_index_to_reg_val[4] = { FR_RX_FREQ_0, FR_RX_FREQ_1, FR_RX_FREQ_2, FR_RX_FREQ_3 }; _iface->poke32(dsp_index_to_reg_val[dspno], freq_word); return (double(freq_word) / scale_factor) * _master_clock_rate; } double usrp1_impl::update_tx_dsp_freq(const size_t dspno, const double freq){ const subdev_spec_pair_t pair = _tx_subdev_spec.at(dspno); //determine the connection type and hence, the sign const std::string conn = _tree->access(str(boost::format( "/mboards/0/dboards/%s/tx_frontends/%s/connection" ) % pair.db_name % pair.sd_name)).get(); double sign = (conn == "I" or conn == "IQ")? +1.0 : -1.0; //map this DSP's subdev spec to a particular codec chip _dbc[pair.db_name].codec->set_duc_freq(sign*freq, _master_clock_rate); return freq; //assume infinite precision } /*********************************************************************** * Async Data **********************************************************************/ bool usrp1_impl::recv_async_msg( async_metadata_t &async_metadata, double timeout ){ boost::this_thread::disable_interruption di; //disable because the wait can throw return _soft_time_ctrl->get_async_queue().pop_with_timed_wait(async_metadata, timeout); } /*********************************************************************** * Receive streamer **********************************************************************/ rx_streamer::sptr usrp1_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.clear(); //NOTE: we have no choice about the channel mapping for (size_t ch = 0; ch < _rx_subdev_spec.size(); ch++){ args.channels.push_back(ch); } if (args.otw_format == "sc16"){ _iface->poke32(FR_RX_FORMAT, 0 | (0 << bmFR_RX_FORMAT_SHIFT_SHIFT) | (16 << bmFR_RX_FORMAT_WIDTH_SHIFT) | bmFR_RX_FORMAT_WANT_Q ); } else if (args.otw_format == "sc8"){ _iface->poke32(FR_RX_FORMAT, 0 | (8 << bmFR_RX_FORMAT_SHIFT_SHIFT) | (8 << bmFR_RX_FORMAT_WIDTH_SHIFT) | bmFR_RX_FORMAT_WANT_Q ); } else{ throw uhd::value_error("USRP1 RX cannot handle requested wire format: " + args.otw_format); } //calculate packet size const size_t bpp = _data_transport->get_recv_frame_size()/args.channels.size(); const size_t spp = bpp/convert::get_bytes_per_item(args.otw_format); //make the new streamer given the samples per packet boost::shared_ptr my_streamer = boost::make_shared(spp, _soft_time_ctrl); //init some streamer stuff my_streamer->set_tick_rate(_master_clock_rate); my_streamer->set_vrt_unpacker(&usrp1_bs_vrt_unpacker); my_streamer->set_xport_chan_get_buff(0, boost::bind( &uhd::transport::zero_copy_if::get_recv_buff, _io_impl->data_transport, _1 )); //set the converter uhd::convert::id_type id; id.input_format = args.otw_format + "_item16_usrp1"; id.num_inputs = 1; id.output_format = args.cpu_format; id.num_outputs = args.channels.size(); my_streamer->set_converter(id); //special scale factor change for sc8 if (args.otw_format == "sc8") my_streamer->set_scale_factor(1.0/127); //save as weak ptr for update access _rx_streamer = my_streamer; //sets all tick and samp rates on this streamer this->update_rates(); return my_streamer; } /*********************************************************************** * Transmit streamer **********************************************************************/ tx_streamer::sptr usrp1_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.clear(); //NOTE: we have no choice about the channel mapping for (size_t ch = 0; ch < _tx_subdev_spec.size(); ch++){ args.channels.push_back(ch); } if (args.otw_format != "sc16"){ throw uhd::value_error("USRP1 TX cannot handle requested wire format: " + args.otw_format); } _iface->poke32(FR_TX_FORMAT, bmFR_TX_FORMAT_16_IQ); //calculate packet size size_t bpp = _data_transport->get_send_frame_size()/args.channels.size(); bpp -= alignment_padding - 1; //minus the max remainder after LUT commit const size_t spp = bpp/convert::get_bytes_per_item(args.otw_format); //make the new streamer given the samples per packet boost::function tx_fcn = boost::bind(&usrp1_impl::tx_stream_on_off, this, _1); boost::shared_ptr my_streamer = boost::make_shared(spp, _soft_time_ctrl, tx_fcn); //init some streamer stuff my_streamer->set_tick_rate(_master_clock_rate); my_streamer->set_vrt_packer(&usrp1_bs_vrt_packer); my_streamer->set_xport_chan_get_buff(0, boost::bind( &usrp1_impl::io_impl::get_send_buff, _io_impl.get(), _1 )); //set the converter uhd::convert::id_type id; id.input_format = args.cpu_format; id.num_inputs = args.channels.size(); id.output_format = args.otw_format + "_item16_usrp1"; id.num_outputs = 1; my_streamer->set_converter(id); //save as weak ptr for update access _tx_streamer = my_streamer; //sets all tick and samp rates on this streamer this->update_rates(); return my_streamer; }