// // 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 . // #include "convert_common.hpp" #include #include using namespace uhd::convert; static const size_t sc16_table_len = size_t(1 << 16); typedef boost::uint16_t (*tohost16_type)(boost::uint16_t); /*********************************************************************** * Implementation for sc16 lookup table * - Lookup the real and imaginary parts individually **********************************************************************/ template class convert_sc16_item32_1_to_fcxx_1 : public converter{ public: convert_sc16_item32_1_to_fcxx_1(void): _table(sc16_table_len){} void set_scalar(const double scalar){ for (size_t i = 0; i < sc16_table_len; i++){ const boost::uint16_t val = tohost(boost::uint16_t(i & 0xffff)); _table[i] = type(boost::int16_t(val)*scalar); } } void operator()(const input_type &inputs, const output_type &outputs, const size_t nsamps){ const item32_t *input = reinterpret_cast(inputs[0]); std::complex *output = reinterpret_cast *>(outputs[0]); for (size_t i = 0; i < nsamps; i++){ const item32_t item = input[i]; output[i] = std::complex( _table[boost::uint16_t(item >> re_shift)], _table[boost::uint16_t(item >> im_shift)] ); } } private: std::vector _table; }; /*********************************************************************** * Implementation for sc8 lookup table * - Lookup the real and imaginary parts together **********************************************************************/ template class convert_sc8_item32_1_to_fcxx_1 : public converter{ public: convert_sc8_item32_1_to_fcxx_1(void): _table(sc16_table_len){} void set_scalar(const double scalar){ for (size_t i = 0; i < sc16_table_len; i++){ const boost::uint16_t val = tohost(boost::uint16_t(i & 0xffff)); const type real = type(boost::int8_t(val >> 8)*scalar); const type imag = type(boost::int8_t(val >> 0)*scalar); _table[i] = std::complex(real, imag); } } void operator()(const input_type &inputs, const output_type &outputs, const size_t nsamps){ const item32_t *input = reinterpret_cast(size_t(inputs[0]) & ~0x3); std::complex *output = reinterpret_cast *>(outputs[0]); size_t num_samps = nsamps; if ((size_t(inputs[0]) & 0x3) != 0){ const item32_t item0 = *input++; *output++ = _table[boost::uint16_t(item0 >> hi_shift)]; num_samps--; } const size_t num_pairs = num_samps/2; for (size_t i = 0, j = 0; i < num_pairs; i++, j+=2){ const item32_t item_i = (input[i]); output[j] = _table[boost::uint16_t(item_i >> lo_shift)]; output[j + 1] = _table[boost::uint16_t(item_i >> hi_shift)]; } if (num_samps != num_pairs*2){ const item32_t item_n = input[num_pairs]; output[num_samps-1] = _table[boost::uint16_t(item_n >> lo_shift)]; } } private: std::vector > _table; }; /*********************************************************************** * Factory functions and registration **********************************************************************/ #ifdef BOOST_BIG_ENDIAN # define SHIFT_PAIR0 16, 0 # define SHIFT_PAIR1 0, 16 #else # define SHIFT_PAIR0 0, 16 # define SHIFT_PAIR1 16, 0 #endif static converter::sptr make_convert_sc16_item32_be_1_to_fc32_1(void){ return converter::sptr(new convert_sc16_item32_1_to_fcxx_1()); } static converter::sptr make_convert_sc16_item32_be_1_to_fc64_1(void){ return converter::sptr(new convert_sc16_item32_1_to_fcxx_1()); } static converter::sptr make_convert_sc16_item32_le_1_to_fc32_1(void){ return converter::sptr(new convert_sc16_item32_1_to_fcxx_1()); } static converter::sptr make_convert_sc16_item32_le_1_to_fc64_1(void){ return converter::sptr(new convert_sc16_item32_1_to_fcxx_1()); } static converter::sptr make_convert_sc8_item32_be_1_to_fc32_1(void){ return converter::sptr(new convert_sc8_item32_1_to_fcxx_1()); } static converter::sptr make_convert_sc8_item32_be_1_to_fc64_1(void){ return converter::sptr(new convert_sc8_item32_1_to_fcxx_1()); } static converter::sptr make_convert_sc8_item32_le_1_to_fc32_1(void){ return converter::sptr(new convert_sc8_item32_1_to_fcxx_1()); } static converter::sptr make_convert_sc8_item32_le_1_to_fc64_1(void){ return converter::sptr(new convert_sc8_item32_1_to_fcxx_1()); } UHD_STATIC_BLOCK(register_convert_sc16_item32_1_to_fcxx_1){ uhd::convert::id_type id; id.num_inputs = 1; id.num_outputs = 1; id.output_format = "fc32"; id.input_format = "sc16_item32_be"; uhd::convert::register_converter(id, &make_convert_sc16_item32_be_1_to_fc32_1, PRIORITY_TABLE); id.output_format = "fc64"; id.input_format = "sc16_item32_be"; uhd::convert::register_converter(id, &make_convert_sc16_item32_be_1_to_fc64_1, PRIORITY_TABLE); id.output_format = "fc32"; id.input_format = "sc16_item32_le"; uhd::convert::register_converter(id, &make_convert_sc16_item32_le_1_to_fc32_1, PRIORITY_TABLE); id.output_format = "fc64"; id.input_format = "sc16_item32_le"; uhd::convert::register_converter(id, &make_convert_sc16_item32_le_1_to_fc64_1, PRIORITY_TABLE); id.output_format = "fc32"; id.input_format = "sc8_item32_be"; uhd::convert::register_converter(id, &make_convert_sc8_item32_be_1_to_fc32_1, PRIORITY_TABLE); id.output_format = "fc64"; id.input_format = "sc8_item32_be"; uhd::convert::register_converter(id, &make_convert_sc8_item32_be_1_to_fc64_1, PRIORITY_TABLE); id.output_format = "fc32"; id.input_format = "sc8_item32_le"; uhd::convert::register_converter(id, &make_convert_sc8_item32_le_1_to_fc32_1, PRIORITY_TABLE); id.output_format = "fc64"; id.input_format = "sc8_item32_le"; uhd::convert::register_converter(id, &make_convert_sc8_item32_le_1_to_fc64_1, PRIORITY_TABLE); }