// // Copyright 2011 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 . // #ifndef INCLUDED_LIBUHD_TRANSPORT_SUPER_RECV_PACKET_HANDLER_HPP #define INCLUDED_LIBUHD_TRANSPORT_SUPER_RECV_PACKET_HANDLER_HPP #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include namespace uhd{ namespace transport{ namespace sph{ UHD_INLINE boost::uint32_t get_context_code( const boost::uint32_t *vrt_hdr, const vrt::if_packet_info_t &if_packet_info ){ //extract the context word (we dont know the endianness so mirror the bytes) boost::uint32_t word0 = vrt_hdr[if_packet_info.num_header_words32] | uhd::byteswap(vrt_hdr[if_packet_info.num_header_words32]); return word0 & 0xff; } typedef boost::function handle_overflow_type; static inline void handle_overflow_nop(void){} /*********************************************************************** * Super receive packet handler * * A receive packet handler represents a group of channels. * The channel group shares a common sample rate. * All channels are received in unison in recv(). **********************************************************************/ class recv_packet_handler{ public: typedef boost::function get_buff_type; typedef void(*vrt_unpacker_type)(const boost::uint32_t *, vrt::if_packet_info_t &); //typedef boost::function vrt_unpacker_type; /*! * Make a new packet handler for receive * \param size the number of transport channels */ recv_packet_handler(const size_t size = 1): _queue_error_for_next_call(false), _buffers_infos_index(0) { this->resize(size); set_alignment_failure_threshold(1000); this->set_scale_factor(1/32767.); } //! Resize the number of transport channels void resize(const size_t size){ if (this->size() == size) return; _props.resize(size); //re-initialize all buffers infos by re-creating the vector _buffers_infos = std::vector(4, buffers_info_type(size)); } //! Get the channel width of this handler size_t size(void) const{ return _props.size(); } //! Setup the vrt unpacker function and offset void set_vrt_unpacker(const vrt_unpacker_type &vrt_unpacker, const size_t header_offset_words32 = 0){ _vrt_unpacker = vrt_unpacker; _header_offset_words32 = header_offset_words32; } /*! * Set the threshold for alignment failure. * How many packets throw out before giving up? * \param threshold number of packets per channel */ void set_alignment_failure_threshold(const size_t threshold){ _alignment_faulure_threshold = threshold*this->size(); } //! Set the rate of ticks per second void set_tick_rate(const double rate){ _tick_rate = rate; } //! Set the rate of samples per second void set_samp_rate(const double rate){ _samp_rate = rate; } /*! * Set the function to get a managed buffer. * \param xport_chan which transport channel * \param get_buff the getter function */ void set_xport_chan_get_buff(const size_t xport_chan, const get_buff_type &get_buff){ _props.at(xport_chan).get_buff = get_buff; } /*! * Setup the conversion functions (homogeneous across transports). * Here, we load a table of converters for all possible io types. * This makes the converter look-up an O(1) operation. * \param otw_type the channel data type * \param width the streams per channel (usually 1) */ void set_converter(const uhd::otw_type_t &otw_type, const size_t width = 1){ _io_buffs.resize(width); _converters.resize(128); for (size_t io_type = 0; io_type < _converters.size(); io_type++){ try{ _converters[io_type] = uhd::convert::get_converter_otw_to_cpu( io_type_t::tid_t(io_type), otw_type, 1, width ); }catch(const uhd::value_error &){} //we expect this, not all io_types valid... } _bytes_per_item = otw_type.get_sample_size(); } //! Set the transport channel's overflow handler void set_overflow_handler(const size_t xport_chan, const handle_overflow_type &handle_overflow){ _props.at(xport_chan).handle_overflow = handle_overflow; } //! Get a scoped lock object for this instance boost::mutex::scoped_lock get_scoped_lock(void){ return boost::mutex::scoped_lock(_mutex); } //! Set the scale factor used in float conversion void set_scale_factor(const double scale_factor){ _scale_factor = scale_factor; } /******************************************************************* * Receive: * The entry point for the fast-path receive calls. * Dispatch into combinations of single packet receive calls. ******************************************************************/ UHD_INLINE size_t recv( const uhd::device::recv_buffs_type &buffs, const size_t nsamps_per_buff, uhd::rx_metadata_t &metadata, const uhd::io_type_t &io_type, uhd::device::recv_mode_t recv_mode, double timeout ){ boost::mutex::scoped_lock lock(_mutex); //handle metadata queued from a previous receive if (_queue_error_for_next_call){ _queue_error_for_next_call = false; metadata = _queue_metadata; //We want to allow a full buffer recv to be cut short by a timeout, //but do not want to generate an inline timeout message packet. if (_queue_metadata.error_code != rx_metadata_t::ERROR_CODE_TIMEOUT) return 0; } switch(recv_mode){ //////////////////////////////////////////////////////////////// case uhd::device::RECV_MODE_ONE_PACKET:{ //////////////////////////////////////////////////////////////// return recv_one_packet(buffs, nsamps_per_buff, metadata, io_type, timeout); } //////////////////////////////////////////////////////////////// case uhd::device::RECV_MODE_FULL_BUFF:{ //////////////////////////////////////////////////////////////// size_t accum_num_samps = recv_one_packet( buffs, nsamps_per_buff, metadata, io_type, timeout ); //first recv had an error code set, return immediately if (metadata.error_code != rx_metadata_t::ERROR_CODE_NONE) return accum_num_samps; //loop until buffer is filled or error code while(accum_num_samps < nsamps_per_buff){ size_t num_samps = recv_one_packet( buffs, nsamps_per_buff - accum_num_samps, _queue_metadata, io_type, timeout, accum_num_samps*io_type.size ); //metadata had an error code set, store for next call and return if (_queue_metadata.error_code != rx_metadata_t::ERROR_CODE_NONE){ _queue_error_for_next_call = true; break; } accum_num_samps += num_samps; } return accum_num_samps; } default: throw uhd::value_error("unknown recv mode"); }//switch(recv_mode) } private: boost::mutex _mutex; vrt_unpacker_type _vrt_unpacker; size_t _header_offset_words32; double _tick_rate, _samp_rate; bool _queue_error_for_next_call; size_t _alignment_faulure_threshold; rx_metadata_t _queue_metadata; struct xport_chan_props_type{ xport_chan_props_type(void): packet_count(0), handle_overflow(&handle_overflow_nop) {} get_buff_type get_buff; size_t packet_count; handle_overflow_type handle_overflow; }; std::vector _props; std::vector _io_buffs; //used in conversion size_t _bytes_per_item; //used in conversion std::vector _converters; //used in conversion double _scale_factor; //! information stored for a received buffer struct per_buffer_info_type{ managed_recv_buffer::sptr buff; const boost::uint32_t *vrt_hdr; vrt::if_packet_info_t ifpi; time_spec_t time; const char *copy_buff; }; //!information stored for a set of aligned buffers struct buffers_info_type : std::vector { buffers_info_type(const size_t size): std::vector(size), indexes_todo(size, true), alignment_time_valid(false), data_bytes_to_copy(0), fragment_offset_in_samps(0) {/* NOP */} boost::dynamic_bitset<> indexes_todo; //used in alignment logic time_spec_t alignment_time; //used in alignment logic bool alignment_time_valid; //used in alignment logic size_t data_bytes_to_copy; //keeps track of state size_t fragment_offset_in_samps; //keeps track of state rx_metadata_t metadata; //packet description }; //! a circular queue of buffer infos std::vector _buffers_infos; size_t _buffers_infos_index; buffers_info_type &get_curr_buffer_info(void){return _buffers_infos[_buffers_infos_index];} buffers_info_type &get_prev_buffer_info(void){return _buffers_infos[(_buffers_infos_index + 3)%4];} buffers_info_type &get_next_buffer_info(void){return _buffers_infos[(_buffers_infos_index + 1)%4];} void increment_buffer_info(void){_buffers_infos_index = (_buffers_infos_index + 1)%4;} //! possible return options for the packet receiver enum packet_type{ PACKET_IF_DATA, PACKET_TIMESTAMP_ERROR, PACKET_INLINE_MESSAGE, PACKET_TIMEOUT_ERROR, PACKET_SEQUENCE_ERROR }; /******************************************************************* * Get and process a single packet from the transport: * Receive a single packet at the given index. * Extract all the relevant info and store. * Check the info to determine the return code. ******************************************************************/ UHD_INLINE packet_type get_and_process_single_packet( const size_t index, buffers_info_type &prev_buffer_info, buffers_info_type &curr_buffer_info, double timeout ){ //get a single packet from the transport layer managed_recv_buffer::sptr &buff = curr_buffer_info[index].buff; buff = _props[index].get_buff(timeout); if (buff.get() == NULL) return PACKET_TIMEOUT_ERROR; //bounds check before extract size_t num_packet_words32 = buff->size()/sizeof(boost::uint32_t); if (num_packet_words32 <= _header_offset_words32){ throw std::runtime_error("recv buffer smaller than vrt packet offset"); } //extract packet info per_buffer_info_type &info = curr_buffer_info[index]; info.ifpi.num_packet_words32 = num_packet_words32 - _header_offset_words32; info.vrt_hdr = buff->cast() + _header_offset_words32; _vrt_unpacker(info.vrt_hdr, info.ifpi); info.time = time_spec_t(time_t(info.ifpi.tsi), size_t(info.ifpi.tsf), _tick_rate); //assumes has_tsi and has_tsf are true info.copy_buff = reinterpret_cast(info.vrt_hdr + info.ifpi.num_header_words32); //-------------------------------------------------------------- //-- Determine return conditions: //-- The order of these checks is HOLY. //-------------------------------------------------------------- //1) check for inline IF message packets if (info.ifpi.packet_type != vrt::if_packet_info_t::PACKET_TYPE_DATA){ return PACKET_INLINE_MESSAGE; } //2) check for sequence errors #ifndef SRPH_DONT_CHECK_SEQUENCE const size_t expected_packet_count = _props[index].packet_count; _props[index].packet_count = (info.ifpi.packet_count + 1)%16; if (expected_packet_count != info.ifpi.packet_count){ return PACKET_SEQUENCE_ERROR; } #endif //3) check for out of order timestamps if (info.ifpi.has_tsi and info.ifpi.has_tsf and prev_buffer_info[index].time > info.time){ return PACKET_TIMESTAMP_ERROR; } //4) otherwise the packet is normal! return PACKET_IF_DATA; } /******************************************************************* * Alignment check: * Check the received packet for alignment and mark accordingly. ******************************************************************/ UHD_INLINE void alignment_check( const size_t index, buffers_info_type &info ){ //if alignment time was not valid or if the sequence id is newer: // use this index's time as the alignment time // reset the indexes list and remove this index if (not info.alignment_time_valid or info[index].time > info.alignment_time){ info.alignment_time_valid = true; info.alignment_time = info[index].time; info.indexes_todo.set(); info.indexes_todo.reset(index); info.data_bytes_to_copy = info[index].ifpi.num_payload_words32*sizeof(boost::uint32_t); } //if the sequence id matches: // remove this index from the list and continue else if (info[index].time == info.alignment_time){ info.indexes_todo.reset(index); } //if the sequence id is older: // continue with the same index to try again //else if (info[index].time < info.alignment_time)... } /******************************************************************* * Get aligned buffers: * Iterate through each index and try to accumulate aligned buffers. * Handle all of the edge cases like inline messages and errors. * The logic will throw out older packets until it finds a match. ******************************************************************/ UHD_INLINE void get_aligned_buffs(double timeout){ increment_buffer_info(); //increment to next buffer buffers_info_type &prev_info = get_prev_buffer_info(); buffers_info_type &curr_info = get_curr_buffer_info(); buffers_info_type &next_info = get_next_buffer_info(); //Loop until we get a message of an aligned set of buffers: // - Receive a single packet and extract its info. // - Handle the packet type yielded by the receive. // - Check the timestamps for alignment conditions. size_t iterations = 0; while (curr_info.indexes_todo.any()){ //get the index to process for this iteration const size_t index = curr_info.indexes_todo.find_first(); packet_type packet; //receive a single packet from the transport try{ packet = get_and_process_single_packet( index, prev_info, curr_info, timeout ); } //handle the case when the get packet throws catch(const std::exception &e){ UHD_MSG(error) << boost::format( "The receive packet handler caught an exception.\n%s" ) % e.what() << std::endl; std::swap(curr_info, next_info); //save progress from curr -> next curr_info.metadata.has_time_spec = false; curr_info.metadata.time_spec = time_spec_t(0.0); curr_info.metadata.more_fragments = false; curr_info.metadata.fragment_offset = 0; curr_info.metadata.start_of_burst = false; curr_info.metadata.end_of_burst = false; curr_info.metadata.error_code = rx_metadata_t::ERROR_CODE_BAD_PACKET; return; } switch(packet){ case PACKET_IF_DATA: alignment_check(index, curr_info); break; case PACKET_TIMESTAMP_ERROR: //If the user changes the device time while streaming or without flushing, //we can receive a packet that comes before the previous packet in time. //This could cause the alignment logic to discard future received packets. //Therefore, when this occurs, we reset the info to restart from scratch. if (curr_info.alignment_time_valid and curr_info.alignment_time != curr_info[index].time){ curr_info.alignment_time_valid = false; } alignment_check(index, curr_info); break; case PACKET_INLINE_MESSAGE: std::swap(curr_info, next_info); //save progress from curr -> next curr_info.metadata.has_time_spec = next_info[index].ifpi.has_tsi and next_info[index].ifpi.has_tsf; curr_info.metadata.time_spec = next_info[index].time; curr_info.metadata.more_fragments = false; curr_info.metadata.fragment_offset = 0; curr_info.metadata.start_of_burst = false; curr_info.metadata.end_of_burst = false; curr_info.metadata.error_code = rx_metadata_t::error_code_t(get_context_code(next_info[index].vrt_hdr, next_info[index].ifpi)); if (curr_info.metadata.error_code == rx_metadata_t::ERROR_CODE_OVERFLOW){ _props[index].handle_overflow(); UHD_MSG(fastpath) << "O"; } return; case PACKET_TIMEOUT_ERROR: std::swap(curr_info, next_info); //save progress from curr -> next curr_info.metadata.has_time_spec = false; curr_info.metadata.time_spec = time_spec_t(0.0); curr_info.metadata.more_fragments = false; curr_info.metadata.fragment_offset = 0; curr_info.metadata.start_of_burst = false; curr_info.metadata.end_of_burst = false; curr_info.metadata.error_code = rx_metadata_t::ERROR_CODE_TIMEOUT; return; case PACKET_SEQUENCE_ERROR: alignment_check(index, curr_info); std::swap(curr_info, next_info); //save progress from curr -> next curr_info.metadata.has_time_spec = prev_info.metadata.has_time_spec; curr_info.metadata.time_spec = prev_info.metadata.time_spec + time_spec_t(0, prev_info[index].ifpi.num_payload_words32*sizeof(boost::uint32_t)/_bytes_per_item, _samp_rate); curr_info.metadata.more_fragments = false; curr_info.metadata.fragment_offset = 0; curr_info.metadata.start_of_burst = false; curr_info.metadata.end_of_burst = false; curr_info.metadata.error_code = rx_metadata_t::ERROR_CODE_OVERFLOW; UHD_MSG(fastpath) << "O"; return; } //too many iterations: detect alignment failure if (iterations++ > _alignment_faulure_threshold){ UHD_MSG(error) << boost::format( "The receive packet handler failed to time-align packets.\n" "%u received packets were processed by the handler.\n" "However, a timestamp match could not be determined.\n" ) % iterations << std::endl; std::swap(curr_info, next_info); //save progress from curr -> next curr_info.metadata.has_time_spec = false; curr_info.metadata.time_spec = time_spec_t(0.0); curr_info.metadata.more_fragments = false; curr_info.metadata.fragment_offset = 0; curr_info.metadata.start_of_burst = false; curr_info.metadata.end_of_burst = false; curr_info.metadata.error_code = rx_metadata_t::ERROR_CODE_ALIGNMENT; return; } } //set the metadata from the buffer information at index zero curr_info.metadata.has_time_spec = curr_info[0].ifpi.has_tsi and curr_info[0].ifpi.has_tsf; curr_info.metadata.time_spec = curr_info[0].time; curr_info.metadata.more_fragments = false; curr_info.metadata.fragment_offset = 0; /* TODO SOB on RX not supported in hardware static const int tlr_sob_flags = (1 << 21) | (1 << 9); //enable and indicator bits curr_info.metadata.start_of_burst = curr_info[0].ifpi.has_tlr and (int(curr_info[0].ifpi.tlr & tlr_sob_flags) != 0); */ curr_info.metadata.start_of_burst = false; static const int tlr_eob_flags = (1 << 20) | (1 << 8); //enable and indicator bits curr_info.metadata.end_of_burst = curr_info[0].ifpi.has_tlr and (int(curr_info[0].ifpi.tlr & tlr_eob_flags) != 0); curr_info.metadata.error_code = rx_metadata_t::ERROR_CODE_NONE; } /******************************************************************* * Receive a single packet: * Handles fragmentation, messages, errors, and copy-conversion. * When no fragments are available, call the get aligned buffers. * Then copy-convert available data into the user's IO buffers. ******************************************************************/ UHD_INLINE size_t recv_one_packet( const uhd::device::recv_buffs_type &buffs, const size_t nsamps_per_buff, uhd::rx_metadata_t &metadata, const uhd::io_type_t &io_type, double timeout, const size_t buffer_offset_bytes = 0 ){ //get the next buffer if the current one has expired if (get_curr_buffer_info().data_bytes_to_copy == 0){ //reset current buffer info members for reuse get_curr_buffer_info().fragment_offset_in_samps = 0; get_curr_buffer_info().alignment_time_valid = false; get_curr_buffer_info().indexes_todo.set(); //perform receive with alignment logic get_aligned_buffs(timeout); } buffers_info_type &info = get_curr_buffer_info(); metadata = info.metadata; //interpolate the time spec (useful when this is a fragment) metadata.time_spec += time_spec_t(0, info.fragment_offset_in_samps, _samp_rate); //extract the number of samples available to copy const size_t nsamps_available = info.data_bytes_to_copy/_bytes_per_item; const size_t nsamps_to_copy = std::min(nsamps_per_buff*_io_buffs.size(), nsamps_available); const size_t bytes_to_copy = nsamps_to_copy*_bytes_per_item; const size_t nsamps_to_copy_per_io_buff = nsamps_to_copy/_io_buffs.size(); size_t buff_index = 0; BOOST_FOREACH(per_buffer_info_type &buff_info, info){ //fill a vector with pointers to the io buffers BOOST_FOREACH(void *&io_buff, _io_buffs){ io_buff = reinterpret_cast(buffs[buff_index++]) + buffer_offset_bytes; } //copy-convert the samples from the recv buffer _converters[io_type.tid](buff_info.copy_buff, _io_buffs, nsamps_to_copy_per_io_buff, _scale_factor); //update the rx copy buffer to reflect the bytes copied buff_info.copy_buff += bytes_to_copy; } //update the copy buffer's availability info.data_bytes_to_copy -= bytes_to_copy; //setup the fragment flags and offset metadata.more_fragments = info.data_bytes_to_copy != 0; metadata.fragment_offset = info.fragment_offset_in_samps; info.fragment_offset_in_samps += nsamps_to_copy; //set for next call return nsamps_to_copy_per_io_buff; } }; }}} //namespace #endif /* INCLUDED_LIBUHD_TRANSPORT_SUPER_RECV_PACKET_HANDLER_HPP */