From 99c2730bc9db270560671f2d7d173768465ed51f Mon Sep 17 00:00:00 2001 From: Martin Braun Date: Mon, 31 Oct 2016 14:30:52 -0700 Subject: Remove all boost:: namespace prefix for uint32_t, int32_t etc. (fixed-width types) - Also removes all references to boost/cstdint.hpp and replaces it with stdint.h (The 'correct' replacement would be , but not all of our compilers support that). --- .../usrp/common/ad9361_driver/ad9361_device.cpp | 296 ++++++++++----------- 1 file changed, 148 insertions(+), 148 deletions(-) (limited to 'host/lib/usrp/common/ad9361_driver/ad9361_device.cpp') diff --git a/host/lib/usrp/common/ad9361_driver/ad9361_device.cpp b/host/lib/usrp/common/ad9361_driver/ad9361_device.cpp index 095017bb6..45ebf78bf 100644 --- a/host/lib/usrp/common/ad9361_driver/ad9361_device.cpp +++ b/host/lib/usrp/common/ad9361_driver/ad9361_device.cpp @@ -25,7 +25,7 @@ #include #include #include -#include +#include #include #include #include @@ -107,9 +107,9 @@ const double ad9361_device_t::DEFAULT_TX_FREQ = 850e6; * how many taps are in the filter, and given a vector of the taps * themselves. */ -void ad9361_device_t::_program_fir_filter(direction_t direction, chain_t chain, int num_taps, boost::uint16_t *coeffs) +void ad9361_device_t::_program_fir_filter(direction_t direction, chain_t chain, int num_taps, uint16_t *coeffs) { - boost::uint16_t base; + uint16_t base; /* RX and TX filters use largely identical sets of programming registers. Select the appropriate bank of registers here. */ @@ -120,9 +120,9 @@ void ad9361_device_t::_program_fir_filter(direction_t direction, chain_t chain, } /* Encode number of filter taps for programming register */ - boost::uint8_t reg_numtaps = (((num_taps / 16) - 1) & 0x07) << 5; + uint8_t reg_numtaps = (((num_taps / 16) - 1) & 0x07) << 5; - boost::uint8_t reg_chain = 0; + uint8_t reg_chain = 0; switch (chain) { case CHAIN_1: reg_chain = 0x01 << 3; @@ -182,25 +182,25 @@ void ad9361_device_t::_program_fir_filter(direction_t direction, chain_t chain, /* Program the RX FIR Filter. */ -void ad9361_device_t::_setup_rx_fir(size_t num_taps, boost::int32_t decimation) +void ad9361_device_t::_setup_rx_fir(size_t num_taps, int32_t decimation) { if (not (decimation == 1 or decimation == 2 or decimation == 4)) { throw uhd::runtime_error("[ad9361_device_t] Invalid Rx FIR decimation."); } - boost::scoped_array coeffs(new boost::uint16_t[num_taps]); + boost::scoped_array coeffs(new uint16_t[num_taps]); for (size_t i = 0; i < num_taps; i++) { switch (num_taps) { case 128: - coeffs[i] = boost::uint16_t((decimation==4) ? fir_128_x4_coeffs[i] : hb127_coeffs[i]); + coeffs[i] = uint16_t((decimation==4) ? fir_128_x4_coeffs[i] : hb127_coeffs[i]); break; case 96: - coeffs[i] = boost::uint16_t((decimation==4) ? fir_96_x4_coeffs[i] : hb95_coeffs[i]); + coeffs[i] = uint16_t((decimation==4) ? fir_96_x4_coeffs[i] : hb95_coeffs[i]); break; case 64: - coeffs[i] = boost::uint16_t((decimation==4) ? fir_64_x4_coeffs[i] : hb63_coeffs[i]); + coeffs[i] = uint16_t((decimation==4) ? fir_64_x4_coeffs[i] : hb63_coeffs[i]); break; case 48: - coeffs[i] = boost::uint16_t((decimation==4) ? fir_48_x4_coeffs[i] : hb47_coeffs[i]); + coeffs[i] = uint16_t((decimation==4) ? fir_48_x4_coeffs[i] : hb47_coeffs[i]); break; default: throw uhd::runtime_error("[ad9361_device_t] Unsupported number of Rx FIR taps."); @@ -211,7 +211,7 @@ void ad9361_device_t::_setup_rx_fir(size_t num_taps, boost::int32_t decimation) } /* Program the TX FIR Filter. */ -void ad9361_device_t::_setup_tx_fir(size_t num_taps, boost::int32_t interpolation) +void ad9361_device_t::_setup_tx_fir(size_t num_taps, int32_t interpolation) { if (not (interpolation == 1 or interpolation == 2 or interpolation == 4)) { throw uhd::runtime_error("[ad9361_device_t] Invalid Tx FIR interpolation."); @@ -219,20 +219,20 @@ void ad9361_device_t::_setup_tx_fir(size_t num_taps, boost::int32_t interpolatio if (interpolation == 1 and num_taps > 64) { throw uhd::runtime_error("[ad9361_device_t] Too many Tx FIR taps for interpolation value."); } - boost::scoped_array coeffs(new boost::uint16_t[num_taps]); + boost::scoped_array coeffs(new uint16_t[num_taps]); for (size_t i = 0; i < num_taps; i++) { switch (num_taps) { case 128: - coeffs[i] = boost::uint16_t((interpolation==4) ? fir_128_x4_coeffs[i] : hb127_coeffs[i]); + coeffs[i] = uint16_t((interpolation==4) ? fir_128_x4_coeffs[i] : hb127_coeffs[i]); break; case 96: - coeffs[i] = boost::uint16_t((interpolation==4) ? fir_96_x4_coeffs[i] : hb95_coeffs[i]); + coeffs[i] = uint16_t((interpolation==4) ? fir_96_x4_coeffs[i] : hb95_coeffs[i]); break; case 64: - coeffs[i] = boost::uint16_t((interpolation==4) ? fir_64_x4_coeffs[i] : hb63_coeffs[i]); + coeffs[i] = uint16_t((interpolation==4) ? fir_64_x4_coeffs[i] : hb63_coeffs[i]); break; case 48: - coeffs[i] = boost::uint16_t((interpolation==4) ? fir_48_x4_coeffs[i] : hb47_coeffs[i]); + coeffs[i] = uint16_t((interpolation==4) ? fir_48_x4_coeffs[i] : hb47_coeffs[i]); break; default: throw uhd::runtime_error("[ad9361_device_t] Unsupported number of Tx FIR taps."); @@ -335,16 +335,16 @@ double ad9361_device_t::_calibrate_baseband_rx_analog_filter(double req_rfbw) } double rxtune_clk = ((1.4 * bbbw * 2 * M_PI) / M_LN2); - _rx_bbf_tunediv = std::min(511, boost::uint16_t(std::ceil(_bbpll_freq / rxtune_clk))); + _rx_bbf_tunediv = std::min(511, uint16_t(std::ceil(_bbpll_freq / rxtune_clk))); _regs.bbftune_config = (_regs.bbftune_config & 0xFE) | ((_rx_bbf_tunediv >> 8) & 0x0001); double bbbw_mhz = bbbw / 1e6; double temp = ((bbbw_mhz - std::floor(bbbw_mhz)) * 1000) / 7.8125; - boost::uint8_t bbbw_khz = std::min(127, boost::uint8_t(std::floor(temp + 0.5))); + uint8_t bbbw_khz = std::min(127, uint8_t(std::floor(temp + 0.5))); /* Set corner frequencies and dividers. */ - _io_iface->poke8(0x1fb, (boost::uint8_t) (bbbw_mhz)); + _io_iface->poke8(0x1fb, (uint8_t) (bbbw_mhz)); _io_iface->poke8(0x1fc, bbbw_khz); _io_iface->poke8(0x1f8, (_rx_bbf_tunediv & 0x00FF)); _io_iface->poke8(0x1f9, _regs.bbftune_config); @@ -402,7 +402,7 @@ double ad9361_device_t::_calibrate_baseband_tx_analog_filter(double req_rfbw) } double txtune_clk = ((1.6 * bbbw * 2 * M_PI) / M_LN2); - boost::uint16_t txbbfdiv = std::min(511, boost::uint16_t(std::ceil(_bbpll_freq / txtune_clk))); + uint16_t txbbfdiv = std::min(511, uint16_t(std::ceil(_bbpll_freq / txtune_clk))); _regs.bbftune_mode = (_regs.bbftune_mode & 0xFE) | ((txbbfdiv >> 8) & 0x0001); @@ -481,7 +481,7 @@ double ad9361_device_t::_calibrate_secondary_tx_filter(double req_rfbw) cap = 63; } - boost::uint8_t reg0d0, reg0d1, reg0d2; + uint8_t reg0d0, reg0d1, reg0d2; /* Translate baseband bandwidths to register settings. */ if ((bbbw_mhz * 2) <= 9) { @@ -526,14 +526,14 @@ double ad9361_device_t::_calibrate_secondary_tx_filter(double req_rfbw) * UG570 page 33 states that this filter should be calibrated to 2.5 * bbbw */ double ad9361_device_t::_calibrate_rx_TIAs(double req_rfbw) { - boost::uint8_t reg1eb = _io_iface->peek8(0x1eb) & 0x3F; - boost::uint8_t reg1ec = _io_iface->peek8(0x1ec) & 0x7F; - boost::uint8_t reg1e6 = _io_iface->peek8(0x1e6) & 0x07; - boost::uint8_t reg1db = 0x00; - boost::uint8_t reg1dc = 0x00; - boost::uint8_t reg1dd = 0x00; - boost::uint8_t reg1de = 0x00; - boost::uint8_t reg1df = 0x00; + uint8_t reg1eb = _io_iface->peek8(0x1eb) & 0x3F; + uint8_t reg1ec = _io_iface->peek8(0x1ec) & 0x7F; + uint8_t reg1e6 = _io_iface->peek8(0x1e6) & 0x07; + uint8_t reg1db = 0x00; + uint8_t reg1dc = 0x00; + uint8_t reg1dd = 0x00; + uint8_t reg1de = 0x00; + uint8_t reg1df = 0x00; double bbbw = req_rfbw / 2.0; @@ -572,12 +572,12 @@ double ad9361_device_t::_calibrate_rx_TIAs(double req_rfbw) if (CTIA_fF > 2920) { reg1dc = 0x40; reg1de = 0x40; - boost::uint8_t temp = (boost::uint8_t) std::min(127, - boost::uint8_t(std::floor(0.5 + ((CTIA_fF - 400.0) / 320.0)))); + uint8_t temp = (uint8_t) std::min(127, + uint8_t(std::floor(0.5 + ((CTIA_fF - 400.0) / 320.0)))); reg1dd = temp; reg1df = temp; } else { - boost::uint8_t temp = boost::uint8_t(std::floor(0.5 + ((CTIA_fF - 400.0) / 40.0)) + 0x40); + uint8_t temp = uint8_t(std::floor(0.5 + ((CTIA_fF - 400.0) / 40.0)) + 0x40); reg1dc = temp; reg1de = temp; reg1dd = 0; @@ -613,9 +613,9 @@ void ad9361_device_t::_setup_adc() bbbw_mhz = 0.20; } - boost::uint8_t rxbbf_c3_msb = _io_iface->peek8(0x1eb) & 0x3F; - boost::uint8_t rxbbf_c3_lsb = _io_iface->peek8(0x1ec) & 0x7F; - boost::uint8_t rxbbf_r2346 = _io_iface->peek8(0x1e6) & 0x07; + uint8_t rxbbf_c3_msb = _io_iface->peek8(0x1eb) & 0x3F; + uint8_t rxbbf_c3_lsb = _io_iface->peek8(0x1ec) & 0x7F; + uint8_t rxbbf_r2346 = _io_iface->peek8(0x1e6) & 0x07; double fsadc = _adcclock_freq / 1e6; @@ -644,71 +644,71 @@ void ad9361_device_t::_setup_adc() /* Calculate the values for all 40 settings registers. * * DO NOT TOUCH THIS UNLESS YOU KNOW EXACTLY WHAT YOU ARE DOING. kthx.*/ - boost::uint8_t data[40]; + uint8_t data[40]; data[0] = 0; data[1] = 0; data[2] = 0; data[3] = 0x24; data[4] = 0x24; data[5] = 0; data[6] = 0; - data[7] = std::min(124, boost::uint8_t(std::floor(-0.5 + data[7] = std::min(124, uint8_t(std::floor(-0.5 + (80.0 * scale_snr * scale_res * std::min(1.0, sqrt(maxsnr * fsadc / 640.0)))))); double data007 = data[7]; - data[8] = std::min(255, boost::uint8_t(std::floor(0.5 + data[8] = std::min(255, uint8_t(std::floor(0.5 + ((20.0 * (640.0 / fsadc) * ((data007 / 80.0)) / (scale_res * scale_cap)))))); - data[10] = std::min(127, boost::uint8_t(std::floor(-0.5 + (77.0 * scale_res + data[10] = std::min(127, uint8_t(std::floor(-0.5 + (77.0 * scale_res * std::min(1.0, sqrt(maxsnr * fsadc / 640.0)))))); double data010 = data[10]; - data[9] = std::min(127, boost::uint8_t(std::floor(0.8 * data010))); - data[11] = std::min(255, boost::uint8_t(std::floor(0.5 + data[9] = std::min(127, uint8_t(std::floor(0.8 * data010))); + data[11] = std::min(255, uint8_t(std::floor(0.5 + (20.0 * (640.0 / fsadc) * ((data010 / 77.0) / (scale_res * scale_cap)))))); - data[12] = std::min(127, boost::uint8_t(std::floor(-0.5 + data[12] = std::min(127, uint8_t(std::floor(-0.5 + (80.0 * scale_res * std::min(1.0, sqrt(maxsnr * fsadc / 640.0)))))); double data012 = data[12]; - data[13] = std::min(255, boost::uint8_t(std::floor(-1.5 + data[13] = std::min(255, uint8_t(std::floor(-1.5 + (20.0 * (640.0 / fsadc) * ((data012 / 80.0) / (scale_res * scale_cap)))))); - data[14] = 21 * boost::uint8_t(std::floor(0.1 * 640.0 / fsadc)); - data[15] = std::min(127, boost::uint8_t(1.025 * data007)); + data[14] = 21 * uint8_t(std::floor(0.1 * 640.0 / fsadc)); + data[15] = std::min(127, uint8_t(1.025 * data007)); double data015 = data[15]; - data[16] = std::min(127, boost::uint8_t(std::floor((data015 + data[16] = std::min(127, uint8_t(std::floor((data015 * (0.98 + (0.02 * std::max(1.0, (640.0 / fsadc) / maxsnr))))))); data[17] = data[15]; - data[18] = std::min(127, boost::uint8_t(0.975 * (data010))); + data[18] = std::min(127, uint8_t(0.975 * (data010))); double data018 = data[18]; - data[19] = std::min(127, boost::uint8_t(std::floor((data018 + data[19] = std::min(127, uint8_t(std::floor((data018 * (0.98 + (0.02 * std::max(1.0, (640.0 / fsadc) / maxsnr))))))); data[20] = data[18]; - data[21] = std::min(127, boost::uint8_t(0.975 * data012)); + data[21] = std::min(127, uint8_t(0.975 * data012)); double data021 = data[21]; - data[22] = std::min(127, boost::uint8_t(std::floor((data021 + data[22] = std::min(127, uint8_t(std::floor((data021 * (0.98 + (0.02 * std::max(1.0, (640.0 / fsadc) / maxsnr))))))); data[23] = data[21]; data[24] = 0x2e; - data[25] = boost::uint8_t(std::floor(128.0 + std::min(63.0, + data[25] = uint8_t(std::floor(128.0 + std::min(63.0, 63.0 * (fsadc / 640.0)))); - data[26] = boost::uint8_t(std::floor(std::min(63.0, 63.0 * (fsadc / 640.0) + data[26] = uint8_t(std::floor(std::min(63.0, 63.0 * (fsadc / 640.0) * (0.92 + (0.08 * (640.0 / fsadc)))))); - data[27] = boost::uint8_t(std::floor(std::min(63.0, + data[27] = uint8_t(std::floor(std::min(63.0, 32.0 * sqrt(fsadc / 640.0)))); - data[28] = boost::uint8_t(std::floor(128.0 + std::min(63.0, + data[28] = uint8_t(std::floor(128.0 + std::min(63.0, 63.0 * (fsadc / 640.0)))); - data[29] = boost::uint8_t(std::floor(std::min(63.0, + data[29] = uint8_t(std::floor(std::min(63.0, 63.0 * (fsadc / 640.0) * (0.92 + (0.08 * (640.0 / fsadc)))))); - data[30] = boost::uint8_t(std::floor(std::min(63.0, + data[30] = uint8_t(std::floor(std::min(63.0, 32.0 * sqrt(fsadc / 640.0)))); - data[31] = boost::uint8_t(std::floor(128.0 + std::min(63.0, + data[31] = uint8_t(std::floor(128.0 + std::min(63.0, 63.0 * (fsadc / 640.0)))); - data[32] = boost::uint8_t(std::floor(std::min(63.0, + data[32] = uint8_t(std::floor(std::min(63.0, 63.0 * (fsadc / 640.0) * (0.92 + (0.08 * (640.0 / fsadc)))))); - data[33] = boost::uint8_t(std::floor(std::min(63.0, + data[33] = uint8_t(std::floor(std::min(63.0, 63.0 * sqrt(fsadc / 640.0)))); - data[34] = std::min(127, boost::uint8_t(std::floor(64.0 + data[34] = std::min(127, uint8_t(std::floor(64.0 * sqrt(fsadc / 640.0)))); data[35] = 0x40; data[36] = 0x40; @@ -848,8 +848,8 @@ void ad9361_device_t::_tx_quadrature_cal_routine() { * 3) Re-read 0A3 to get bits [5:0] because maybe they changed? * 4) Update only the TX NCO freq bits in 0A3. * 5) Profit (I hope). */ - boost::uint8_t reg0a3 = _io_iface->peek8(0x0a3); - boost::uint8_t nco_freq = (reg0a3 & 0xC0); + uint8_t reg0a3 = _io_iface->peek8(0x0a3); + uint8_t nco_freq = (reg0a3 & 0xC0); _io_iface->poke8(0x0a0, 0x15 | (nco_freq >> 1)); reg0a3 = _io_iface->peek8(0x0a3); _io_iface->poke8(0x0a3, (reg0a3 & 0x3F) | nco_freq); @@ -916,7 +916,7 @@ void ad9361_device_t::_calibrate_tx_quadrature() /* This calibration must be done in a certain order, and for both TX_A * and TX_B, separately. Store the original setting so that we can * restore it later. */ - boost::uint8_t orig_reg_inputsel = _regs.inputsel; + uint8_t orig_reg_inputsel = _regs.inputsel; /*********************************************************************** * TX1/2-A Calibration @@ -951,9 +951,9 @@ void ad9361_device_t::_calibrate_tx_quadrature() * Note that this table is fixed for all frequency settings. */ void ad9361_device_t::_program_mixer_gm_subtable() { - boost::uint8_t gain[] = { 0x78, 0x74, 0x70, 0x6C, 0x68, 0x64, 0x60, 0x5C, 0x58, + uint8_t gain[] = { 0x78, 0x74, 0x70, 0x6C, 0x68, 0x64, 0x60, 0x5C, 0x58, 0x54, 0x50, 0x4C, 0x48, 0x30, 0x18, 0x00 }; - boost::uint8_t gm[] = { 0x00, 0x0D, 0x15, 0x1B, 0x21, 0x25, 0x29, 0x2C, 0x2F, 0x31, + uint8_t gm[] = { 0x00, 0x0D, 0x15, 0x1B, 0x21, 0x25, 0x29, 0x2C, 0x2F, 0x31, 0x33, 0x34, 0x35, 0x3A, 0x3D, 0x3E }; /* Start the clock. */ @@ -984,8 +984,8 @@ void ad9361_device_t::_program_mixer_gm_subtable() void ad9361_device_t::_program_gain_table() { /* Figure out which gain table we should be using for our current * frequency band. */ - boost::uint8_t (*gain_table)[3] = NULL; - boost::uint8_t new_gain_table; + uint8_t (*gain_table)[3] = NULL; + uint8_t new_gain_table; if (_rx_freq < 1300e6) { gain_table = gain_table_sub_1300mhz; new_gain_table = 1; @@ -1012,7 +1012,7 @@ void ad9361_device_t::_program_gain_table() { _io_iface->poke8(0x137, 0x1A); /* IT'S PROGRAMMING TIME. */ - boost::uint8_t index = 0; + uint8_t index = 0; for (; index < 77; index++) { _io_iface->poke8(0x130, index); _io_iface->poke8(0x131, gain_table[index][0]); @@ -1118,18 +1118,18 @@ void ad9361_device_t::_setup_synth(direction_t direction, double vcorate) throw uhd::runtime_error("[ad9361_device_t] vcoindex > 53"); /* Parse the values out of the LUT based on our calculated index... */ - boost::uint8_t vco_output_level = synth_cal_lut[vcoindex][0]; - boost::uint8_t vco_varactor = synth_cal_lut[vcoindex][1]; - boost::uint8_t vco_bias_ref = synth_cal_lut[vcoindex][2]; - boost::uint8_t vco_bias_tcf = synth_cal_lut[vcoindex][3]; - boost::uint8_t vco_cal_offset = synth_cal_lut[vcoindex][4]; - boost::uint8_t vco_varactor_ref = synth_cal_lut[vcoindex][5]; - boost::uint8_t charge_pump_curr = synth_cal_lut[vcoindex][6]; - boost::uint8_t loop_filter_c2 = synth_cal_lut[vcoindex][7]; - boost::uint8_t loop_filter_c1 = synth_cal_lut[vcoindex][8]; - boost::uint8_t loop_filter_r1 = synth_cal_lut[vcoindex][9]; - boost::uint8_t loop_filter_c3 = synth_cal_lut[vcoindex][10]; - boost::uint8_t loop_filter_r3 = synth_cal_lut[vcoindex][11]; + uint8_t vco_output_level = synth_cal_lut[vcoindex][0]; + uint8_t vco_varactor = synth_cal_lut[vcoindex][1]; + uint8_t vco_bias_ref = synth_cal_lut[vcoindex][2]; + uint8_t vco_bias_tcf = synth_cal_lut[vcoindex][3]; + uint8_t vco_cal_offset = synth_cal_lut[vcoindex][4]; + uint8_t vco_varactor_ref = synth_cal_lut[vcoindex][5]; + uint8_t charge_pump_curr = synth_cal_lut[vcoindex][6]; + uint8_t loop_filter_c2 = synth_cal_lut[vcoindex][7]; + uint8_t loop_filter_c1 = synth_cal_lut[vcoindex][8]; + uint8_t loop_filter_r1 = synth_cal_lut[vcoindex][9]; + uint8_t loop_filter_c3 = synth_cal_lut[vcoindex][10]; + uint8_t loop_filter_r3 = synth_cal_lut[vcoindex][11]; /* ... annnd program! */ if (direction == RX) { @@ -1566,7 +1566,7 @@ void ad9361_device_t::initialize() boost::this_thread::sleep(boost::posix_time::milliseconds(20)); /* Check device ID to make sure iface works */ - boost::uint32_t device_id = (_io_iface->peek8(0x037) & 0x8); + uint32_t device_id = (_io_iface->peek8(0x037) & 0x8); if (device_id != 0x8) { throw uhd::runtime_error(str(boost::format("[ad9361_device_t::initialize] Device ID readback failure. Expected: 0x8, Received: 0x%x") % device_id)); } @@ -1631,9 +1631,9 @@ void ad9361_device_t::initialize() /* Data delay for TX and RX data clocks */ digital_interface_delays_t timing = _client_params->get_digital_interface_timing(); - boost::uint8_t rx_delays = ((timing.rx_clk_delay & 0xF) << 4) + uint8_t rx_delays = ((timing.rx_clk_delay & 0xF) << 4) | (timing.rx_data_delay & 0xF); - boost::uint8_t tx_delays = ((timing.tx_clk_delay & 0xF) << 4) + uint8_t tx_delays = ((timing.tx_clk_delay & 0xF) << 4) | (timing.tx_data_delay & 0xF); _io_iface->poke8(0x006, rx_delays); _io_iface->poke8(0x007, tx_delays); @@ -1811,7 +1811,7 @@ double ad9361_device_t::set_clock_rate(const double req_rate) /* We must be in the SLEEP / WAIT state to do this. If we aren't already * there, transition the ENSM to State 0. */ - boost::uint8_t current_state = _io_iface->peek8(0x017) & 0x0F; + uint8_t current_state = _io_iface->peek8(0x017) & 0x0F; switch (current_state) { case 0x05: /* We are in the ALERT state. */ @@ -1833,8 +1833,8 @@ double ad9361_device_t::set_clock_rate(const double req_rate) /* Store the current chain / antenna selections so that we can restore * them at the end of this routine; all chains will be enabled from * within setup_rates for calibration purposes. */ - boost::uint8_t orig_tx_chains = _regs.txfilt & 0xC0; - boost::uint8_t orig_rx_chains = _regs.rxfilt & 0xC0; + uint8_t orig_tx_chains = _regs.txfilt & 0xC0; + uint8_t orig_rx_chains = _regs.rxfilt & 0xC0; /* Call into the clock configuration / settings function. This is where * all the hard work gets done. */ @@ -1962,8 +1962,8 @@ void ad9361_device_t::set_active_chains(bool tx1, bool tx2, bool rx1, bool rx2) } /* Check for FDD state */ - boost::uint8_t set_back_to_fdd = 0; - boost::uint8_t ensm_state = _io_iface->peek8(0x017) & 0x0F; + uint8_t set_back_to_fdd = 0; + uint8_t ensm_state = _io_iface->peek8(0x017) & 0x0F; if (ensm_state == 0xA) // FDD { /* Put into ALERT state (via the FDD flush state). */ @@ -2124,7 +2124,7 @@ double ad9361_device_t::set_gain(direction_t direction, chain_t chain, const dou * outside this function. */ double atten = AD9361_MAX_GAIN - value; - boost::uint32_t attenreg = boost::uint32_t(atten * 4); + uint32_t attenreg = uint32_t(atten * 4); if (chain == CHAIN_1) { _tx1_gain = value; _io_iface->poke8(0x073, attenreg & 0xFF); @@ -2166,8 +2166,8 @@ void ad9361_device_t::data_port_loopback(const bool loopback_enabled) * -0.25dB / bit 9bit resolution.*/ double ad9361_device_t::get_rssi(chain_t chain) { - boost::uint32_t reg_rssi = 0; - boost::uint8_t lsb_bit_pos = 0; + uint32_t reg_rssi = 0; + uint8_t lsb_bit_pos = 0; if (chain == CHAIN_1) { reg_rssi = 0x1A7; lsb_bit_pos = 0; @@ -2175,9 +2175,9 @@ double ad9361_device_t::get_rssi(chain_t chain) reg_rssi = 0x1A9; lsb_bit_pos = 1; } - boost::uint8_t msbs = _io_iface->peek8(reg_rssi); - boost::uint8_t lsb = ((_io_iface->peek8(0x1AB)) >> lsb_bit_pos) & 0x01; - boost::uint16_t val = ((msbs << 1) | lsb); + uint8_t msbs = _io_iface->peek8(reg_rssi); + uint8_t lsb = ((_io_iface->peek8(0x1AB)) >> lsb_bit_pos) & 0x01; + uint16_t val = ((msbs << 1) | lsb); double rssi = (-0.25f * ((double)val)); //-0.25dB/lsb (See Gain Control Users Guide p. 25) return rssi; } @@ -2190,7 +2190,7 @@ double ad9361_device_t::get_rssi(chain_t chain) double ad9361_device_t::_get_temperature(const double cal_offset, const double timeout) { //set 0x01D[0] to 1 to disable AuxADC GPIO reading - boost::uint8_t tmp = 0; + uint8_t tmp = 0; tmp = _io_iface->peek8(0x01D); _io_iface->poke8(0x01D, (tmp | 0x01)); _io_iface->poke8(0x00B, 0); //set offset to 0 @@ -2209,7 +2209,7 @@ double ad9361_device_t::_get_temperature(const double cal_offset, const double t } _io_iface->poke8(0x00C, 0x00); //clear read flag - boost::uint8_t temp = _io_iface->peek8(0x00E); //read temperature. + uint8_t temp = _io_iface->peek8(0x00E); //read temperature. double tmp_temp = temp/1.140f; //according to ADI driver tmp_temp = tmp_temp + cal_offset; //Constant offset acquired by one point calibration. @@ -2275,9 +2275,9 @@ void ad9361_device_t::set_iq_balance_auto(direction_t direction, const bool on) * the gain configuration will be reloaded. */ void ad9361_device_t::_setup_agc(chain_t chain, gain_mode_t gain_mode) { - boost::uint8_t gain_mode_reg = 0; - boost::uint8_t gain_mode_prev = 0; - boost::uint8_t gain_mode_bits_pos = 0; + uint8_t gain_mode_reg = 0; + uint8_t gain_mode_prev = 0; + uint8_t gain_mode_bits_pos = 0; gain_mode_reg = _io_iface->peek8(0x0FA); gain_mode_prev = (gain_mode_reg & 0x0F); @@ -2306,7 +2306,7 @@ void ad9361_device_t::_setup_agc(chain_t chain, gain_mode_t gain_mode) throw uhd::runtime_error("[ad9361_device_t] Gain mode does not exist"); } _io_iface->poke8(0x0FA, gain_mode_reg); - boost::uint8_t gain_mode_status = _io_iface->peek8(0x0FA); + uint8_t gain_mode_status = _io_iface->peek8(0x0FA); gain_mode_status = (gain_mode_status & 0x0F); /*Check if gain mode configuration needs to be reprogrammed*/ if (((gain_mode_prev == 0) && (gain_mode_status != 0)) || ((gain_mode_prev != 0) && (gain_mode_status == 0))) { @@ -2434,16 +2434,16 @@ double ad9361_device_t::set_bw_filter(direction_t direction, const double rf_bw) return (2.0 * set_analog_bb_bw); } -void ad9361_device_t::_set_fir_taps(direction_t direction, chain_t chain, const std::vector& taps) +void ad9361_device_t::_set_fir_taps(direction_t direction, chain_t chain, const std::vector& taps) { size_t num_taps = taps.size(); size_t num_taps_avail = _get_num_fir_taps(direction); if(num_taps == num_taps_avail) { - boost::scoped_array coeffs(new boost::uint16_t[num_taps_avail]); + boost::scoped_array coeffs(new uint16_t[num_taps_avail]); for (size_t i = 0; i < num_taps_avail; i++) { - coeffs[i] = boost::uint16_t(taps[i]); + coeffs[i] = uint16_t(taps[i]); } _program_fir_filter(direction, chain, num_taps_avail, coeffs.get()); } else if(num_taps < num_taps_avail){ @@ -2455,7 +2455,7 @@ void ad9361_device_t::_set_fir_taps(direction_t direction, chain_t chain, const size_t ad9361_device_t::_get_num_fir_taps(direction_t direction) { - boost::uint8_t num = 0; + uint8_t num = 0; if(direction == RX) num = _io_iface->peek8(0x0F5); else @@ -2466,7 +2466,7 @@ size_t ad9361_device_t::_get_num_fir_taps(direction_t direction) size_t ad9361_device_t::_get_fir_dec_int(direction_t direction) { - boost::uint8_t dec_int = 0; + uint8_t dec_int = 0; if(direction == RX) dec_int = _io_iface->peek8(0x003); else @@ -2484,12 +2484,12 @@ size_t ad9361_device_t::_get_fir_dec_int(direction_t direction) return dec_int; } -std::vector ad9361_device_t::_get_fir_taps(direction_t direction, chain_t chain) +std::vector ad9361_device_t::_get_fir_taps(direction_t direction, chain_t chain) { int base; size_t num_taps = _get_num_fir_taps(direction); - boost::uint8_t config; - boost::uint8_t reg_numtaps = (((num_taps / 16) - 1) & 0x07) << 5; + uint8_t config; + uint8_t reg_numtaps = (((num_taps / 16) - 1) & 0x07) << 5; config = reg_numtaps | 0x02; //start the programming clock if(chain == CHAIN_1) @@ -2510,17 +2510,17 @@ std::vector ad9361_device_t::_get_fir_taps(direction_t direction _io_iface->poke8(base+5,config); - std::vector taps; - boost::uint8_t lower_val; - boost::uint8_t higher_val; - boost::uint16_t coeff; + std::vector taps; + uint8_t lower_val; + uint8_t higher_val; + uint16_t coeff; for(size_t i = 0;i < num_taps;i++) { _io_iface->poke8(base,0x00+i); lower_val = _io_iface->peek8(base+3); higher_val = _io_iface->peek8(base+4); coeff = ((higher_val << 8) | lower_val); - taps.push_back(boost::int16_t(coeff)); + taps.push_back(int16_t(coeff)); } config = (config & (~(1 << 1))); //disable filter clock @@ -2569,16 +2569,16 @@ filter_info_base::sptr ad9361_device_t::_get_filter_lp_bb(direction_t direction) * For TX direction the INT3 is returned. */ filter_info_base::sptr ad9361_device_t::_get_filter_dec_int_3(direction_t direction) { - boost::uint8_t enable = 0; + uint8_t enable = 0; double rate = _adcclock_freq; double full_scale; size_t dec = 0; size_t interpol = 0; filter_info_base::filter_type type = filter_info_base::DIGITAL_I16; std::string name; - boost::int16_t taps_array_rx[] = {55, 83, 0, -393, -580, 0, 1914, 4041, 5120, 4041, 1914, 0, -580, -393, 0, 83, 55}; - boost::int16_t taps_array_tx[] = {36, -19, 0, -156, -12, 0, 479, 233, 0, -1215, -993, 0, 3569, 6277, 8192, 6277, 3569, 0, -993, -1215, 0, 223, 479, 0, -12, -156, 0, -19, 36}; - std::vector taps; + int16_t taps_array_rx[] = {55, 83, 0, -393, -580, 0, 1914, 4041, 5120, 4041, 1914, 0, -580, -393, 0, 83, 55}; + int16_t taps_array_tx[] = {36, -19, 0, -156, -12, 0, 479, 233, 0, -1215, -993, 0, 3569, 6277, 8192, 6277, 3569, 0, -993, -1215, 0, 223, 479, 0, -12, -156, 0, -19, 36}; + std::vector taps; filter_info_base::sptr ret; @@ -2590,14 +2590,14 @@ filter_info_base::sptr ad9361_device_t::_get_filter_dec_int_3(direction_t direct enable = _io_iface->peek8(0x003); enable = ((enable >> 4) & 0x03); - taps.assign(taps_array_rx, taps_array_rx + sizeof(taps_array_rx) / sizeof(boost::int16_t) ); + taps.assign(taps_array_rx, taps_array_rx + sizeof(taps_array_rx) / sizeof(int16_t) ); } else { full_scale = 8192; dec = 1; interpol = 3; - boost::uint8_t use_dac_clk_div = _io_iface->peek8(0x00A); + uint8_t use_dac_clk_div = _io_iface->peek8(0x00A); use_dac_clk_div = ((use_dac_clk_div >> 3) & 0x01); if(use_dac_clk_div == 1) { @@ -2611,24 +2611,24 @@ filter_info_base::sptr ad9361_device_t::_get_filter_dec_int_3(direction_t direct rate /= 3; } - taps.assign(taps_array_tx, taps_array_tx + sizeof(taps_array_tx) / sizeof(boost::int16_t) ); + taps.assign(taps_array_tx, taps_array_tx + sizeof(taps_array_tx) / sizeof(int16_t) ); } - ret = filter_info_base::sptr(new digital_filter_base(type, (enable != 2) ? true : false, 2, rate, interpol, dec, full_scale, taps.size(), taps)); + ret = filter_info_base::sptr(new digital_filter_base(type, (enable != 2) ? true : false, 2, rate, interpol, dec, full_scale, taps.size(), taps)); return ret; } filter_info_base::sptr ad9361_device_t::_get_filter_hb_3(direction_t direction) { - boost::uint8_t enable = 0; + uint8_t enable = 0; double rate = _adcclock_freq; double full_scale = 0; size_t dec = 1; size_t interpol = 1; filter_info_base::filter_type type = filter_info_base::DIGITAL_I16; - boost::int16_t taps_array_rx[] = {1, 4, 6, 4, 1}; - boost::int16_t taps_array_tx[] = {1, 2, 1}; - std::vector taps; + int16_t taps_array_rx[] = {1, 4, 6, 4, 1}; + int16_t taps_array_tx[] = {1, 2, 1}; + std::vector taps; if(direction == RX) { @@ -2637,12 +2637,12 @@ filter_info_base::sptr ad9361_device_t::_get_filter_hb_3(direction_t direction) enable = _io_iface->peek8(0x003); enable = ((enable >> 4) & 0x03); - taps.assign(taps_array_rx, taps_array_rx + sizeof(taps_array_rx) / sizeof(boost::int16_t) ); + taps.assign(taps_array_rx, taps_array_rx + sizeof(taps_array_rx) / sizeof(int16_t) ); } else { full_scale = 2; interpol = 2; - boost::uint8_t use_dac_clk_div = _io_iface->peek8(0x00A); + uint8_t use_dac_clk_div = _io_iface->peek8(0x00A); use_dac_clk_div = ((use_dac_clk_div >> 3) & 0x01); if(use_dac_clk_div == 1) { @@ -2655,26 +2655,26 @@ filter_info_base::sptr ad9361_device_t::_get_filter_hb_3(direction_t direction) { rate /= 2; } - taps.assign(taps_array_tx, taps_array_tx + sizeof(taps_array_tx) / sizeof(boost::int16_t) ); + taps.assign(taps_array_tx, taps_array_tx + sizeof(taps_array_tx) / sizeof(int16_t) ); } - filter_info_base::sptr hb = filter_info_base::sptr(new digital_filter_base(type, (enable != 1) ? true : false, 2, rate, interpol, dec, full_scale, taps.size(), taps)); + filter_info_base::sptr hb = filter_info_base::sptr(new digital_filter_base(type, (enable != 1) ? true : false, 2, rate, interpol, dec, full_scale, taps.size(), taps)); return hb; } filter_info_base::sptr ad9361_device_t::_get_filter_hb_2(direction_t direction) { - boost::uint8_t enable = 0; + uint8_t enable = 0; double rate = _adcclock_freq; double full_scale = 0; size_t dec = 1; size_t interpol = 1; filter_info_base::filter_type type = filter_info_base::DIGITAL_I16; - boost::int16_t taps_array[] = {-9, 0, 73, 128, 73, 0, -9}; - std::vector taps(taps_array, taps_array + sizeof(taps_array) / sizeof(boost::int16_t) ); + int16_t taps_array[] = {-9, 0, 73, 128, 73, 0, -9}; + std::vector taps(taps_array, taps_array + sizeof(taps_array) / sizeof(int16_t) ); - digital_filter_base::sptr hb_3 = boost::dynamic_pointer_cast >(_get_filter_hb_3(direction)); - digital_filter_base::sptr dec_int_3 = boost::dynamic_pointer_cast >(_get_filter_dec_int_3(direction)); + digital_filter_base::sptr hb_3 = boost::dynamic_pointer_cast >(_get_filter_hb_3(direction)); + digital_filter_base::sptr dec_int_3 = boost::dynamic_pointer_cast >(_get_filter_dec_int_3(direction)); if(direction == RX) { @@ -2714,24 +2714,24 @@ filter_info_base::sptr ad9361_device_t::_get_filter_hb_2(direction_t direction) } } - filter_info_base::sptr hb(new digital_filter_base(type, (enable == 0) ? true : false, 3, rate, interpol, dec, full_scale, taps.size(), taps)); + filter_info_base::sptr hb(new digital_filter_base(type, (enable == 0) ? true : false, 3, rate, interpol, dec, full_scale, taps.size(), taps)); return hb; } filter_info_base::sptr ad9361_device_t::_get_filter_hb_1(direction_t direction) { - boost::uint8_t enable = 0; + uint8_t enable = 0; double rate = 0; double full_scale = 0; size_t dec = 1; size_t interpol = 1; filter_info_base::filter_type type = filter_info_base::DIGITAL_I16; - std::vector taps; - boost::int16_t taps_rx_array[] = {-8, 0, 42, 0, -147, 0, 619, 1013, 619, 0, -147, 0, 42, 0, -8}; - boost::int16_t taps_tx_array[] = {-53, 0, 313, 0, -1155, 0, 4989, 8192, 4989, 0, -1155, 0, 313, 0, -53}; + std::vector taps; + int16_t taps_rx_array[] = {-8, 0, 42, 0, -147, 0, 619, 1013, 619, 0, -147, 0, 42, 0, -8}; + int16_t taps_tx_array[] = {-53, 0, 313, 0, -1155, 0, 4989, 8192, 4989, 0, -1155, 0, 313, 0, -53}; - digital_filter_base::sptr hb_2 = boost::dynamic_pointer_cast >(_get_filter_hb_2(direction)); + digital_filter_base::sptr hb_2 = boost::dynamic_pointer_cast >(_get_filter_hb_2(direction)); if(direction == RX) { @@ -2740,7 +2740,7 @@ filter_info_base::sptr ad9361_device_t::_get_filter_hb_1(direction_t direction) enable = _io_iface->peek8(0x003); enable = ((enable >> 2) & 0x01); rate = hb_2->get_output_rate(); - taps.assign(taps_rx_array, taps_rx_array + sizeof(taps_rx_array) / sizeof(boost::int16_t) ); + taps.assign(taps_rx_array, taps_rx_array + sizeof(taps_rx_array) / sizeof(int16_t) ); } else if (direction == TX) { full_scale = 8192; interpol = 2; @@ -2751,10 +2751,10 @@ filter_info_base::sptr ad9361_device_t::_get_filter_hb_1(direction_t direction) { rate /= 2; } - taps.assign(taps_tx_array, taps_tx_array + sizeof(taps_tx_array) / sizeof(boost::int16_t) ); + taps.assign(taps_tx_array, taps_tx_array + sizeof(taps_tx_array) / sizeof(int16_t) ); } - filter_info_base::sptr hb(new digital_filter_base(type, (enable == 0) ? true : false, 4, rate, interpol, dec, full_scale, taps.size(), taps)); + filter_info_base::sptr hb(new digital_filter_base(type, (enable == 0) ? true : false, 4, rate, interpol, dec, full_scale, taps.size(), taps)); return hb; } @@ -2764,9 +2764,9 @@ filter_info_base::sptr ad9361_device_t::_get_filter_fir(direction_t direction, c size_t dec = 1; size_t interpol = 1; size_t max_num_taps = 128; - boost::uint8_t enable = 1; + uint8_t enable = 1; - digital_filter_base::sptr hb_1 = boost::dynamic_pointer_cast >(_get_filter_hb_1(direction)); + digital_filter_base::sptr hb_1 = boost::dynamic_pointer_cast >(_get_filter_hb_1(direction)); if(direction == RX) { @@ -2794,14 +2794,14 @@ filter_info_base::sptr ad9361_device_t::_get_filter_fir(direction_t direction, c } max_num_taps = _get_num_fir_taps(direction); - filter_info_base::sptr fir(new digital_filter_fir(filter_info_base::DIGITAL_FIR_I16, (enable == 0) ? true : false, 5, rate, interpol, dec, 32767, max_num_taps, _get_fir_taps(direction, chain))); + filter_info_base::sptr fir(new digital_filter_fir(filter_info_base::DIGITAL_FIR_I16, (enable == 0) ? true : false, 5, rate, interpol, dec, 32767, max_num_taps, _get_fir_taps(direction, chain))); return fir; } void ad9361_device_t::_set_filter_fir(direction_t direction, chain_t channel, filter_info_base::sptr filter) { - digital_filter_fir::sptr fir = boost::dynamic_pointer_cast >(filter); + digital_filter_fir::sptr fir = boost::dynamic_pointer_cast >(filter); //only write taps. Ignore everything else for now _set_fir_taps(direction, channel, fir->get_taps()); } -- cgit v1.2.3