// // Copyright 2011,2014 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 "clock_ctrl.hpp" #include "ad9522_regs.hpp" #include #include #include #include #include #include #include "b100_regs.hpp" //spi slave constants #include #include #include #include #include //gcd #include #include using namespace uhd; /*********************************************************************** * Constants **********************************************************************/ static const bool ENABLE_THE_TEST_OUT = true; static const double REFERENCE_INPUT_RATE = 10e6; /*********************************************************************** * Helpers **********************************************************************/ template static void set_clock_divider( size_t divider, div_type &low, div_type &high, bypass_type &bypass ){ high = divider/2 - 1; low = divider - high - 2; bypass = (divider == 1)? 1 : 0; } /*********************************************************************** * Clock rate calculation stuff: * Using the internal VCO between 1400 and 1800 MHz **********************************************************************/ struct clock_settings_type{ size_t ref_clock_doubler, r_counter, a_counter, b_counter, prescaler, vco_divider, chan_divider; size_t get_n_counter(void) const{return prescaler * b_counter + a_counter;} double get_ref_rate(void) const{return REFERENCE_INPUT_RATE * ref_clock_doubler;} double get_vco_rate(void) const{return get_ref_rate()/r_counter * get_n_counter();} double get_chan_rate(void) const{return get_vco_rate()/vco_divider;} double get_out_rate(void) const{return get_chan_rate()/chan_divider;} std::string to_pp_string(void) const{ return str(boost::format( " r_counter: %d\n" " a_counter: %d\n" " b_counter: %d\n" " prescaler: %d\n" " vco_divider: %d\n" " chan_divider: %d\n" " vco_rate: %fMHz\n" " chan_rate: %fMHz\n" " out_rate: %fMHz\n" ) % r_counter % a_counter % b_counter % prescaler % vco_divider % chan_divider % (get_vco_rate()/1e6) % (get_chan_rate()/1e6) % (get_out_rate()/1e6) ); } }; //! gives the greatest divisor of num between 1 and max inclusive template static inline T greatest_divisor(T num, T max){ for (T i = max; i > 1; i--) if (num%i == 0) return i; return 1; } //! gives the least divisor of num between min and num exclusive template static inline T least_divisor(T num, T min){ for (T i = min; i < num; i++) if (num%i == 0) return i; return 1; } static clock_settings_type get_clock_settings(double rate){ clock_settings_type cs; cs.ref_clock_doubler = 2; //always doubling cs.prescaler = 8; //set to 8 when input is under 2400 MHz //basic formulas used below: //out_rate*X = ref_rate*Y //X = i*ref_rate/gcd //Y = i*out_rate/gcd //X = chan_div * vco_div * R //Y = P*B + A const boost::uint64_t out_rate = boost::uint64_t(rate); const boost::uint64_t ref_rate = boost::uint64_t(cs.get_ref_rate()); const size_t gcd = size_t(boost::math::gcd(ref_rate, out_rate)); for (size_t i = 1; i <= 100; i++){ const size_t X = size_t(i*ref_rate/gcd); const size_t Y = size_t(i*out_rate/gcd); //determine A and B (P is fixed) cs.b_counter = Y/cs.prescaler; cs.a_counter = Y - cs.b_counter*cs.prescaler; static const double vco_bound_pad = 100e6; for ( //calculate an r divider that fits into the bounds of the vco cs.r_counter = size_t(cs.get_n_counter()*cs.get_ref_rate()/(1800e6 - vco_bound_pad)); cs.r_counter <= size_t(cs.get_n_counter()*cs.get_ref_rate()/(1400e6 + vco_bound_pad)) and cs.r_counter > 0; cs.r_counter++ ){ //determine chan_div and vco_div //and fill in that order of preference cs.chan_divider = greatest_divisor(X/cs.r_counter, 32); cs.vco_divider = greatest_divisor(X/cs.chan_divider/cs.r_counter, 6); //avoid a vco divider of 1 (if possible) if (cs.vco_divider == 1){ cs.vco_divider = least_divisor(cs.chan_divider, 2); cs.chan_divider /= cs.vco_divider; } UHD_LOGV(always) << "gcd " << gcd << std::endl << "X " << X << std::endl << "Y " << Y << std::endl << cs.to_pp_string() << std::endl ; //filter limits on the counters if (cs.vco_divider == 1) continue; if (cs.r_counter >= (1<<14)) continue; if (cs.b_counter == 2) continue; if (cs.b_counter == 1 and cs.a_counter != 0) continue; if (cs.b_counter >= (1<<13)) continue; if (cs.a_counter >= (1<<6)) continue; if (cs.get_vco_rate() > 1800e6 - vco_bound_pad) continue; if (cs.get_vco_rate() < 1400e6 + vco_bound_pad) continue; if (cs.get_out_rate() != rate) continue; UHD_MSG(status) << "USRP-B100 clock control: " << i << std::endl << cs.to_pp_string() << std::endl; return cs; } } throw uhd::value_error(str(boost::format( "USRP-B100 clock control: could not calculate settings for clock rate %fMHz" ) % (rate/1e6))); } b100_clock_ctrl::~b100_clock_ctrl(void) { /* NOP */ } /*********************************************************************** * Clock Control Implementation **********************************************************************/ class b100_clock_ctrl_impl : public b100_clock_ctrl{ public: b100_clock_ctrl_impl(i2c_iface::sptr iface, double master_clock_rate){ _iface = iface; _chan_rate = 0.0; _out_rate = 0.0; //perform soft-reset _ad9522_regs.soft_reset = 1; this->send_reg(0x000); this->latch_regs(); _ad9522_regs.soft_reset = 0; //init the clock gen registers _ad9522_regs.sdo_active = ad9522_regs_t::SDO_ACTIVE_SDO_SDIO; _ad9522_regs.enb_stat_eeprom_at_stat_pin = 0; //use status pin _ad9522_regs.status_pin_control = 0x1; //n divider _ad9522_regs.ld_pin_control = 0x00; //dld _ad9522_regs.refmon_pin_control = 0x12; //show ref2 _ad9522_regs.lock_detect_counter = ad9522_regs_t::LOCK_DETECT_COUNTER_16CYC; this->use_internal_ref(); this->set_fpga_clock_rate(master_clock_rate); //initialize to something this->enable_fpga_clock(true); this->enable_test_clock(ENABLE_THE_TEST_OUT); this->enable_rx_dboard_clock(false); this->enable_tx_dboard_clock(false); } ~b100_clock_ctrl_impl(void){ UHD_SAFE_CALL( this->enable_test_clock(ENABLE_THE_TEST_OUT); this->enable_rx_dboard_clock(false); this->enable_tx_dboard_clock(false); //this->enable_fpga_clock(false); //FIXME ) } /*********************************************************************** * Clock rate control: * - set clock rate w/ internal VCO * - set clock rate w/ external VCXO **********************************************************************/ void set_clock_settings_with_internal_vco(double rate){ const clock_settings_type cs = get_clock_settings(rate); //set the rates to private variables so the implementation knows! _chan_rate = cs.get_chan_rate(); _out_rate = cs.get_out_rate(); _ad9522_regs.enable_clock_doubler = (cs.ref_clock_doubler == 2)? 1 : 0; _ad9522_regs.set_r_counter(cs.r_counter); _ad9522_regs.a_counter = cs.a_counter; _ad9522_regs.set_b_counter(cs.b_counter); UHD_ASSERT_THROW(cs.prescaler == 8); //assumes this below: _ad9522_regs.prescaler_p = ad9522_regs_t::PRESCALER_P_DIV8_9; _ad9522_regs.pll_power_down = ad9522_regs_t::PLL_POWER_DOWN_NORMAL; _ad9522_regs.cp_current = ad9522_regs_t::CP_CURRENT_1_2MA; _ad9522_regs.bypass_vco_divider = 0; switch(cs.vco_divider){ case 1: _ad9522_regs.vco_divider = ad9522_regs_t::VCO_DIVIDER_DIV1; break; case 2: _ad9522_regs.vco_divider = ad9522_regs_t::VCO_DIVIDER_DIV2; break; case 3: _ad9522_regs.vco_divider = ad9522_regs_t::VCO_DIVIDER_DIV3; break; case 4: _ad9522_regs.vco_divider = ad9522_regs_t::VCO_DIVIDER_DIV4; break; case 5: _ad9522_regs.vco_divider = ad9522_regs_t::VCO_DIVIDER_DIV5; break; case 6: _ad9522_regs.vco_divider = ad9522_regs_t::VCO_DIVIDER_DIV6; break; } _ad9522_regs.select_vco_or_clock = ad9522_regs_t::SELECT_VCO_OR_CLOCK_VCO; //setup fpga master clock _ad9522_regs.out0_format = ad9522_regs_t::OUT0_FORMAT_LVDS; set_clock_divider(cs.chan_divider, _ad9522_regs.divider0_low_cycles, _ad9522_regs.divider0_high_cycles, _ad9522_regs.divider0_bypass ); //setup codec clock _ad9522_regs.out3_format = ad9522_regs_t::OUT3_FORMAT_LVDS; set_clock_divider(cs.chan_divider, _ad9522_regs.divider1_low_cycles, _ad9522_regs.divider1_high_cycles, _ad9522_regs.divider1_bypass ); this->send_all_regs(); calibrate_now(); } void set_clock_settings_with_external_vcxo(double rate){ //set the rates to private variables so the implementation knows! _chan_rate = rate; _out_rate = rate; _ad9522_regs.enable_clock_doubler = 1; //doubler always on const double ref_rate = REFERENCE_INPUT_RATE*2; //bypass prescaler such that N = B long gcd = boost::math::gcd(long(ref_rate), long(rate)); _ad9522_regs.set_r_counter(int(ref_rate/gcd)); _ad9522_regs.a_counter = 0; _ad9522_regs.set_b_counter(int(rate/gcd)); _ad9522_regs.prescaler_p = ad9522_regs_t::PRESCALER_P_DIV1; //setup external vcxo _ad9522_regs.pll_power_down = ad9522_regs_t::PLL_POWER_DOWN_NORMAL; _ad9522_regs.cp_current = ad9522_regs_t::CP_CURRENT_1_2MA; _ad9522_regs.bypass_vco_divider = 1; _ad9522_regs.select_vco_or_clock = ad9522_regs_t::SELECT_VCO_OR_CLOCK_EXTERNAL; //setup fpga master clock _ad9522_regs.out0_format = ad9522_regs_t::OUT0_FORMAT_LVDS; _ad9522_regs.divider0_bypass = 1; //setup codec clock _ad9522_regs.out3_format = ad9522_regs_t::OUT3_FORMAT_LVDS; _ad9522_regs.divider1_bypass = 1; this->send_all_regs(); } void set_fpga_clock_rate(double rate){ if (_out_rate == rate) return; if (rate == 61.44e6) set_clock_settings_with_external_vcxo(rate); else set_clock_settings_with_internal_vco(rate); //clock rate changed! update dboard clocks and FPGA ticks per second set_rx_dboard_clock_rate(rate); set_tx_dboard_clock_rate(rate); } double get_fpga_clock_rate(void){ return this->_out_rate; } /*********************************************************************** * FPGA clock enable **********************************************************************/ void enable_fpga_clock(bool enb){ _ad9522_regs.out0_format = ad9522_regs_t::OUT0_FORMAT_LVDS; _ad9522_regs.out0_lvds_power_down = !enb; this->send_reg(0x0F0); this->latch_regs(); } /*********************************************************************** * Special test clock output **********************************************************************/ void enable_test_clock(bool enb){ //setup test clock (same divider as codec clock) _ad9522_regs.out4_format = ad9522_regs_t::OUT4_FORMAT_CMOS; _ad9522_regs.out4_cmos_configuration = (enb)? ad9522_regs_t::OUT4_CMOS_CONFIGURATION_A_ON : ad9522_regs_t::OUT4_CMOS_CONFIGURATION_OFF; this->send_reg(0x0F4); this->latch_regs(); } /*********************************************************************** * RX Dboard Clock Control (output 9, divider 3) **********************************************************************/ void enable_rx_dboard_clock(bool enb){ _ad9522_regs.out9_format = ad9522_regs_t::OUT9_FORMAT_LVDS; _ad9522_regs.out9_lvds_power_down = !enb; this->send_reg(0x0F9); this->latch_regs(); } std::vector get_rx_dboard_clock_rates(void){ std::vector rates; for(size_t div = 1; div <= 16+16; div++) rates.push_back(this->_chan_rate/div); return rates; } void set_rx_dboard_clock_rate(double rate){ assert_has(get_rx_dboard_clock_rates(), rate, "rx dboard clock rate"); _rx_clock_rate = rate; size_t divider = size_t(this->_chan_rate/rate); //set the divider registers set_clock_divider(divider, _ad9522_regs.divider3_low_cycles, _ad9522_regs.divider3_high_cycles, _ad9522_regs.divider3_bypass ); this->send_reg(0x199); this->send_reg(0x19a); this->soft_sync(); } double get_rx_clock_rate(void){ return _rx_clock_rate; } /*********************************************************************** * TX Dboard Clock Control (output 6, divider 2) **********************************************************************/ void enable_tx_dboard_clock(bool enb){ _ad9522_regs.out6_format = ad9522_regs_t::OUT6_FORMAT_LVDS; _ad9522_regs.out6_lvds_power_down = !enb; this->send_reg(0x0F6); this->latch_regs(); } std::vector get_tx_dboard_clock_rates(void){ return get_rx_dboard_clock_rates(); //same master clock, same dividers... } void set_tx_dboard_clock_rate(double rate){ assert_has(get_tx_dboard_clock_rates(), rate, "tx dboard clock rate"); _tx_clock_rate = rate; size_t divider = size_t(this->_chan_rate/rate); //set the divider registers set_clock_divider(divider, _ad9522_regs.divider2_low_cycles, _ad9522_regs.divider2_high_cycles, _ad9522_regs.divider2_bypass ); this->send_reg(0x196); this->send_reg(0x197); this->soft_sync(); } double get_tx_clock_rate(void){ return _tx_clock_rate; } /*********************************************************************** * Clock reference control **********************************************************************/ void use_internal_ref(void) { _ad9522_regs.enable_ref2 = 1; _ad9522_regs.enable_ref1 = 0; _ad9522_regs.select_ref = ad9522_regs_t::SELECT_REF_REF2; _ad9522_regs.enb_auto_ref_switchover = ad9522_regs_t::ENB_AUTO_REF_SWITCHOVER_MANUAL; this->send_reg(0x01C); this->latch_regs(); } void use_external_ref(void) { _ad9522_regs.enable_ref2 = 0; _ad9522_regs.enable_ref1 = 1; _ad9522_regs.select_ref = ad9522_regs_t::SELECT_REF_REF1; _ad9522_regs.enb_auto_ref_switchover = ad9522_regs_t::ENB_AUTO_REF_SWITCHOVER_MANUAL; this->send_reg(0x01C); this->latch_regs(); } void use_auto_ref(void) { _ad9522_regs.enable_ref2 = 1; _ad9522_regs.enable_ref1 = 1; _ad9522_regs.select_ref = ad9522_regs_t::SELECT_REF_REF1; _ad9522_regs.enb_auto_ref_switchover = ad9522_regs_t::ENB_AUTO_REF_SWITCHOVER_AUTO; this->send_reg(0x01C); this->latch_regs(); } bool get_locked(void){ static const boost::uint8_t addr = 0x01F; boost::uint32_t reg = this->read_reg(addr); _ad9522_regs.set_reg(addr, reg); return _ad9522_regs.digital_lock_detect != 0; } private: i2c_iface::sptr _iface; ad9522_regs_t _ad9522_regs; double _out_rate; //rate at the fpga and codec double _chan_rate; //rate before final dividers double _rx_clock_rate, _tx_clock_rate; void latch_regs(void){ _ad9522_regs.io_update = 1; this->send_reg(0x232); } void send_reg(boost::uint16_t addr){ boost::uint32_t reg = _ad9522_regs.get_write_reg(addr); UHD_LOGV(often) << "clock control write reg: " << std::hex << reg << std::endl; byte_vector_t buf; buf.push_back(boost::uint8_t(reg >> 16)); buf.push_back(boost::uint8_t(reg >> 8)); buf.push_back(boost::uint8_t(reg & 0xff)); _iface->write_i2c(0x5C, buf); } boost::uint8_t read_reg(boost::uint16_t addr){ byte_vector_t buf; buf.push_back(boost::uint8_t(addr >> 8)); buf.push_back(boost::uint8_t(addr & 0xff)); _iface->write_i2c(0x5C, buf); buf = _iface->read_i2c(0x5C, 1); return boost::uint32_t(buf[0] & 0xFF); } void calibrate_now(void){ //vco calibration routine: _ad9522_regs.vco_calibration_now = 0; this->send_reg(0x18); this->latch_regs(); _ad9522_regs.vco_calibration_now = 1; this->send_reg(0x18); this->latch_regs(); //wait for calibration done: static const boost::uint8_t addr = 0x01F; for (size_t ms10 = 0; ms10 < 100; ms10++){ boost::this_thread::sleep(boost::posix_time::milliseconds(10)); boost::uint32_t reg = read_reg(addr); _ad9522_regs.set_reg(addr, reg); if (_ad9522_regs.vco_calibration_finished) goto wait_for_ld; } UHD_MSG(error) << "USRP-B100 clock control: VCO calibration timeout" << std::endl; wait_for_ld: //wait for digital lock detect: for (size_t ms10 = 0; ms10 < 100; ms10++){ boost::this_thread::sleep(boost::posix_time::milliseconds(10)); boost::uint32_t reg = read_reg(addr); _ad9522_regs.set_reg(addr, reg); if (_ad9522_regs.digital_lock_detect) return; } UHD_MSG(error) << "USRP-B100 clock control: lock detection timeout" << std::endl; } void soft_sync(void){ _ad9522_regs.soft_sync = 1; this->send_reg(0x230); this->latch_regs(); _ad9522_regs.soft_sync = 0; this->send_reg(0x230); this->latch_regs(); } void send_all_regs(void){ //setup a list of register ranges to write typedef std::pair range_t; static const std::vector ranges = boost::assign::list_of (range_t(0x000, 0x000)) (range_t(0x010, 0x01F)) (range_t(0x0F0, 0x0FD)) (range_t(0x190, 0x19B)) (range_t(0x1E0, 0x1E1)) (range_t(0x230, 0x230)) ; //write initial register values and latch/update BOOST_FOREACH(const range_t &range, ranges){ for(boost::uint16_t addr = range.first; addr <= range.second; addr++){ this->send_reg(addr); } } this->latch_regs(); } }; /*********************************************************************** * Clock Control Make **********************************************************************/ b100_clock_ctrl::sptr b100_clock_ctrl::make(i2c_iface::sptr iface, double master_clock_rate){ return sptr(new b100_clock_ctrl_impl(iface, master_clock_rate)); }