// // Copyright 2008,2009 Free Software Foundation, Inc. // // This file is part of GNU Radio // // GNU Radio 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 asversion 3, or (at your option) // any later version. // // GNU Radio 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 GNU Radio; see the file COPYING. If not, write to // the Free Software Foundation, Inc., 51 Franklin Street, // Boston, MA 02110-1301, USA. // #ifdef HAVE_CONFIG_H #include "config.h" #endif #include #include #if 0 tune_result::tune_result(double baseband, double dxc, double residual, bool inv) : ok(false), baseband_freq(baseband), dxc_freq(dxc), residual_freq(residual), inverted(inv) { } tune_result::~tune_result() { } #endif /*****************************************************************************/ db_base::db_base(usrp_basic_sptr usrp, int which) : d_is_shutdown(false), d_raw_usrp(usrp.get()), d_which(which), d_lo_offset(0.0) { } db_base::~db_base() { shutdown(); } void db_base::shutdown() { if (!d_is_shutdown){ d_is_shutdown = true; // do whatever there is to do to shutdown } } int db_base::dbid() { return usrp()->daughterboard_id(d_which); } std::string db_base::name() { return usrp_dbid_to_string(dbid()); } std::string db_base::side_and_name() { if(d_which == 0) return "A: " + name(); else return "B: " + name(); } // Function to bypass ADC buffers. Any board which is DC-coupled // should bypass the buffers bool db_base::bypass_adc_buffers(bool bypass) { //if(d_tx) { // throw std::runtime_error("TX Board has no adc buffers\n"); //} bool ok = true; if(d_which==0) { ok &= usrp()->set_adc_buffer_bypass(0, bypass); ok &= usrp()->set_adc_buffer_bypass(1, bypass); } else { ok &= usrp()->set_adc_buffer_bypass(2, bypass); ok &= usrp()->set_adc_buffer_bypass(3, bypass); } return ok; } bool db_base::set_atr_mask(int v) { // Set Auto T/R mask. return usrp()->write_atr_mask(d_which, v); } bool db_base::set_atr_txval(int v) { // Set Auto T/R register value to be used when transmitting. return usrp()->write_atr_txval(d_which, v); } bool db_base::set_atr_rxval(int v) { // Set Auto T/R register value to be used when receiving. return usrp()->write_atr_rxval(d_which, v); } bool db_base::set_atr_tx_delay(int v) { // Set Auto T/R delay (in clock ticks) from when Tx fifo gets data to // when T/R switches. return usrp()->write_atr_tx_delay(v); } bool db_base::set_atr_rx_delay(int v) { // Set Auto T/R delay (in clock ticks) from when Tx fifo goes empty to // when T/R switches. return usrp()->write_atr_rx_delay(v); } bool db_base::i_and_q_swapped() { // Return True if this is a quadrature device and (for RX) ADC 0 is Q // or (for TX) DAC 0 is Q return false; } bool db_base::spectrum_inverted() { // Return True if the dboard gives an inverted spectrum return false; } bool db_base::set_enable(bool on) { // For tx daughterboards, this controls the transmitter enable. return true; // default is nop } bool db_base::set_auto_tr(bool on) { // Enable automatic Transmit/Receive switching (ATR). // // Should be overridden in subclasses that care. This will typically // set the atr_mask, txval and rxval. return true; } bool db_base::set_lo_offset(double offset) { // Set how much LO is offset from requested frequency d_lo_offset = offset; return true; } bool db_base::select_rx_antenna(int which_antenna) { // Specify which antenna port to use for reception. // Should be overriden by daughterboards that care. return which_antenna == 0; } bool db_base::select_rx_antenna(const std::string &which_antenna) { // Specify which antenna port to use for reception. // Should be overriden by daughterboards that care. return which_antenna == ""; } // Reference Clock section // // Control whether a reference clock is sent to the daughterboards, // and what frequency // // Bit 7 -- 1 turns on refclk, 0 allows IO use // Bits 6:0 Divider value // double db_base::_refclk_freq() { return usrp()->fpga_master_clock_freq() / _refclk_divisor(); } void db_base::_enable_refclk(bool enable) { int CLOCK_OUT = 1; // Clock is on lowest bit int REFCLK_ENABLE = 0x80; int REFCLK_DIVISOR_MASK = 0x7f; if(enable) { usrp()->_write_oe(d_which, CLOCK_OUT, CLOCK_OUT); // output enable usrp()->write_refclk(d_which, (_refclk_divisor() & REFCLK_DIVISOR_MASK) | REFCLK_ENABLE); } else { usrp()->write_refclk(d_which, 0); } } int db_base::_refclk_divisor() { // Return value to stick in REFCLK_DIVISOR register throw std::runtime_error("_reflck_divisor() called from base class\n");; } bool db_base::set_bw(float bw) { // Set baseband bandwidth (board specific) // Should be overriden by boards that implement variable IF filtering (e.g., DBSRX) return false; } std::ostream &operator<<(std::ostream &os, db_base &x) { os << x.side_and_name(); return os; }