/* -*- c++ -*- */ /* * Copyright 2008,2009 Free Software Foundation, Inc. * * 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 . */ #ifdef HAVE_CONFIG_H #include #endif #include #include "usrp2_impl.h" #include #include #include #include #include #include namespace usrp2 { // --- Table of weak pointers to usrps we know about --- // (Could be cleaned up and turned into a template) struct usrp_table_entry { // inteface + normalized mac addr ("eth0:01:23:45:67:89:ab") std::string key; boost::weak_ptr value; usrp_table_entry(const std::string &_key, boost::weak_ptr _value) : key(_key), value(_value) {} }; typedef std::vector usrp_table; static boost::mutex s_table_mutex; static usrp_table s_table; usrp2::sptr usrp2::find_existing_or_make_new(const std::string &ifc, props *pr, size_t rx_bufsize) { std::string key = ifc + ":" + pr->addr; boost::mutex::scoped_lock guard(s_table_mutex); for (usrp_table::iterator p = s_table.begin(); p != s_table.end();){ if (p->value.expired()) // weak pointer is now dead p = s_table.erase(p); // erase it else { if (key == p->key) // found it return usrp2::sptr(p->value); else ++p; // keep looking } } // We don't have the USRP2 we're looking for // create a new one and stick it in the table. usrp2::sptr r(new usrp2(ifc, pr, rx_bufsize)); usrp_table_entry t(key, r); s_table.push_back(t); return r; } // --- end of table code --- static bool parse_mac_addr(const std::string &s, std::string &ns) { u2_mac_addr_t p; p.addr[0] = 0x00; // Matt's IAB p.addr[1] = 0x50; p.addr[2] = 0xC2; p.addr[3] = 0x85; p.addr[4] = 0x30; p.addr[5] = 0x00; int len = s.size(); switch (len) { case 5: if (sscanf(s.c_str(), "%hhx:%hhx", &p.addr[4], &p.addr[5]) != 2) return false; break; case 17: if (sscanf(s.c_str(), "%hhx:%hhx:%hhx:%hhx:%hhx:%hhx", &p.addr[0], &p.addr[1], &p.addr[2], &p.addr[3], &p.addr[4], &p.addr[5]) != 6) return false; break; default: return false; } char buf[128]; snprintf(buf, sizeof(buf), "%02x:%02x:%02x:%02x:%02x:%02x", p.addr[0],p.addr[1],p.addr[2], p.addr[3],p.addr[4],p.addr[5]); ns = std::string(buf); return true; } usrp2::sptr usrp2::make(const std::string &ifc, const std::string &addr, size_t rx_bufsize) { std::string naddr = ""; if (addr != "" && !parse_mac_addr(addr, naddr)) throw std::runtime_error("Invalid MAC address"); props_vector_t u2s = find(ifc, naddr); int n = u2s.size(); if (n == 0) { if (addr == "") throw std::runtime_error("No USRPs found on interface " + ifc); else throw std::runtime_error("No USRP found with addr " + addr + " on interface " + ifc); } if (n > 1) throw std::runtime_error("Multiple USRPs found on interface; must select by MAC address."); return find_existing_or_make_new(ifc, &u2s[0], rx_bufsize); } // Private constructor. Sole function is to create an impl. usrp2::usrp2(const std::string &ifc, props *p, size_t rx_bufsize) : d_impl(new usrp2::impl(ifc, p, rx_bufsize)) { // NOP } // Public class destructor. d_impl will auto-delete. usrp2::~usrp2() { // NOP } std::string usrp2::mac_addr() { return d_impl->mac_addr(); } std::string usrp2::interface_name() { return d_impl->interface_name(); } // Receive bool usrp2::set_rx_antenna(int ant){ return d_impl->set_rx_antenna(ant); } bool usrp2::set_rx_gain(double gain) { return d_impl->set_rx_gain(gain); } double usrp2::rx_gain_min() { return d_impl->rx_gain_min(); } double usrp2::rx_gain_max() { return d_impl->rx_gain_max(); } double usrp2::rx_gain_db_per_step() { return d_impl->rx_gain_db_per_step(); } bool usrp2::set_rx_lo_offset(double frequency) { return d_impl->set_rx_lo_offset(frequency); } bool usrp2::set_rx_center_freq(double frequency, tune_result *result) { return d_impl->set_rx_center_freq(frequency, result); } double usrp2::rx_freq_min() { return d_impl->rx_freq_min(); } double usrp2::rx_freq_max() { return d_impl->rx_freq_max(); } bool usrp2::set_rx_decim(int decimation_factor) { return d_impl->set_rx_decim(decimation_factor); } int usrp2::rx_decim() { return d_impl->rx_decim(); } bool usrp2::set_rx_scale_iq(int scale_i, int scale_q) { return d_impl->set_rx_scale_iq(scale_i, scale_q); } bool usrp2::start_rx_streaming(unsigned int channel, unsigned int items_per_frame) { return d_impl->start_rx_streaming(channel, items_per_frame); } bool usrp2::start_rx_streaming_at(unsigned int channel, unsigned int items_per_frame, unsigned int time) { return d_impl->start_rx_streaming_at(channel, items_per_frame,time); } bool usrp2::sync_and_start_rx_streaming_at(unsigned int channel, unsigned int items_per_frame, unsigned int time) { return d_impl->sync_and_start_rx_streaming_at(channel, items_per_frame, time); } bool usrp2::rx_samples(unsigned int channel, rx_sample_handler *handler) { return d_impl->rx_samples(channel, handler); } bool usrp2::stop_rx_streaming(unsigned int channel) { return d_impl->stop_rx_streaming(channel); } unsigned int usrp2::rx_overruns() { return d_impl->rx_overruns(); } unsigned int usrp2::rx_missing() { return d_impl->rx_missing(); } // Transmit bool usrp2::set_tx_antenna(int ant){ return d_impl->set_tx_antenna(ant); } bool usrp2::set_tx_gain(double gain) { return d_impl->set_tx_gain(gain); } double usrp2::tx_gain_min() { return d_impl->tx_gain_min(); } double usrp2::tx_gain_max() { return d_impl->tx_gain_max(); } double usrp2::tx_gain_db_per_step() { return d_impl->tx_gain_db_per_step(); } bool usrp2::set_tx_lo_offset(double frequency) { return d_impl->set_tx_lo_offset(frequency); } bool usrp2::set_tx_center_freq(double frequency, tune_result *result) { return d_impl->set_tx_center_freq(frequency, result); } double usrp2::tx_freq_min() { return d_impl->tx_freq_min(); } double usrp2::tx_freq_max() { return d_impl->tx_freq_max(); } bool usrp2::set_tx_interp(int interpolation_factor) { return d_impl->set_tx_interp(interpolation_factor); } int usrp2::tx_interp() { return d_impl->tx_interp(); } void usrp2::default_tx_scale_iq(int interpolation_factor, int *scale_i, int *scale_q) { d_impl->default_tx_scale_iq(interpolation_factor, scale_i, scale_q); } bool usrp2::set_tx_scale_iq(int scale_i, int scale_q) { return d_impl->set_tx_scale_iq(scale_i, scale_q); } bool usrp2::tx_32fc(unsigned int channel, const std::complex *samples, size_t nsamples, const tx_metadata *metadata) { return d_impl->tx_32fc(channel, samples, nsamples, metadata); } bool usrp2::tx_16sc(unsigned int channel, const std::complex *samples, size_t nsamples, const tx_metadata *metadata) { return d_impl->tx_16sc(channel, samples, nsamples, metadata); } bool usrp2::tx_raw(unsigned int channel, const uint32_t *items, size_t nitems, const tx_metadata *metadata) { return d_impl->tx_raw(channel, items, nitems, metadata); } // miscellaneous methods bool usrp2::config_mimo(int flags) { return d_impl->config_mimo(flags); } bool usrp2::fpga_master_clock_freq(long *freq) { return d_impl->fpga_master_clock_freq(freq); } bool usrp2::adc_rate(long *rate) { return d_impl->adc_rate(rate); } bool usrp2::dac_rate(long *rate) { return d_impl->dac_rate(rate); } bool usrp2::tx_daughterboard_id(int *dbid) { return d_impl->tx_daughterboard_id(dbid); } bool usrp2::rx_daughterboard_id(int *dbid) { return d_impl->rx_daughterboard_id(dbid); } // low level methods bool usrp2::burn_mac_addr(const std::string &new_addr) { return d_impl->burn_mac_addr(new_addr); } bool usrp2::sync_to_pps() { return d_impl->sync_to_pps(); } bool usrp2::sync_every_pps(bool enable) { return d_impl->sync_every_pps(enable); } std::vector usrp2::peek32(uint32_t addr, uint32_t words) { return d_impl->peek32(addr, words); } bool usrp2::poke32(uint32_t addr, const std::vector &data) { return d_impl->poke32(addr, data); } bool usrp2::set_gpio_ddr(int bank, uint16_t value, uint16_t mask) { return d_impl->set_gpio_ddr(bank, value, mask); } bool usrp2::set_gpio_sels(int bank, std::string src) { return d_impl->set_gpio_sels(bank, src); } bool usrp2::write_gpio(int bank, uint16_t value, uint16_t mask) { return d_impl->write_gpio(bank, value, mask); } bool usrp2::read_gpio(int bank, uint16_t *value) { return d_impl->read_gpio(bank, value); } bool usrp2::enable_gpio_streaming(int bank, int enable) { return d_impl->enable_gpio_streaming(bank, enable); } } // namespace usrp2 std::ostream& operator<<(std::ostream &os, const usrp2::props &x) { os << x.addr; char buf[128]; snprintf(buf, sizeof(buf)," hw_rev = 0x%04x", x.hw_rev); os << buf; return os; }