gr_sig_source_x.cc.t

来自「这是用python语言写的一个数字广播的信号处理工具包。利用它」· T 代码 · 共 243 行

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/* -*- c++ -*- *//* * Copyright 2004 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 version 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. */// @WARNING@#ifdef HAVE_CONFIG_H#include <config.h>#endif#include <@NAME@.h>#include <algorithm>#include <gr_io_signature.h>#include <stdexcept>#include <gr_complex.h>@NAME@::@NAME@ (double sampling_freq, gr_waveform_t waveform,		double frequency, double ampl, @TYPE@ offset)  : gr_sync_block ("@BASE_NAME@",		   gr_make_io_signature (0, 0, 0),		   gr_make_io_signature (1, 1, sizeof (@TYPE@))),    d_sampling_freq (sampling_freq), d_waveform (waveform), d_frequency (frequency),    d_ampl (ampl), d_offset (offset){  d_nco.set_freq (2 * M_PI * d_frequency / d_sampling_freq);}@NAME@_sptrgr_make_@BASE_NAME@ (double sampling_freq, gr_waveform_t waveform,		     double frequency, double ampl, @TYPE@ offset){  return @NAME@_sptr (new @NAME@ (sampling_freq, waveform, frequency, ampl, offset));}int@NAME@::work (int noutput_items,		    gr_vector_const_void_star &input_items,		    gr_vector_void_star &output_items){  @TYPE@ *optr = (@TYPE@ *) output_items[0];  @TYPE@ t;  switch (d_waveform){#if @IS_COMPLEX@	// complex?  case GR_CONST_WAVE:    t = (gr_complex) d_ampl + d_offset;    for (int i = 0; i < noutput_items; i++)	// FIXME unroll      optr[i] = t;    break;      case GR_SIN_WAVE:  case GR_COS_WAVE:    d_nco.sincos (optr, noutput_items, d_ampl);    if (d_offset == gr_complex(0,0))      break;    for (int i = 0; i < noutput_items; i++){      optr[i] += d_offset;    }    break;      /* Implements a real square wave high from -PI to 0.    * The imaginary square wave leads by 90 deg.  */  case GR_SQR_WAVE:	    for (int i = 0; i < noutput_items; i++){      if (d_nco.get_phase() < -1*M_PI/2)        optr[i] = gr_complex(d_ampl, 0)+d_offset;      else if (d_nco.get_phase() < 0)        optr[i] = gr_complex(d_ampl, d_ampl)+d_offset;      else if (d_nco.get_phase() < M_PI/2)        optr[i] = gr_complex(0, d_ampl)+d_offset;      else        optr[i] = d_offset;		      d_nco.step();    }    break;	  /* Implements a real triangle wave rising from -PI to 0 and    * falling from 0 to PI. The imaginary triangle wave leads by 90 deg.  */  case GR_TRI_WAVE:	    for (int i = 0; i < noutput_items; i++){      if (d_nco.get_phase() < -1*M_PI/2){        optr[i] = gr_complex(d_ampl*d_nco.get_phase()/M_PI + d_ampl,           -1*d_ampl*d_nco.get_phase()/M_PI - d_ampl/2)+d_offset;      }      else if (d_nco.get_phase() < 0){        optr[i] = gr_complex(d_ampl*d_nco.get_phase()/M_PI + d_ampl,          d_ampl*d_nco.get_phase()/M_PI + d_ampl/2)+d_offset;      }      else if (d_nco.get_phase() < M_PI/2){        optr[i] = gr_complex(-1*d_ampl*d_nco.get_phase()/M_PI + d_ampl,           d_ampl*d_nco.get_phase()/M_PI + d_ampl/2)+d_offset;      }      else{        optr[i] = gr_complex(-1*d_ampl*d_nco.get_phase()/M_PI + d_ampl,           -1*d_ampl*d_nco.get_phase()/M_PI + 3*d_ampl/2)+d_offset;      }      d_nco.step();    }    break;	  /* Implements a real saw tooth wave rising from -PI to PI.   * The imaginary saw tooth wave leads by 90 deg.  */  case GR_SAW_WAVE:	    for (int i = 0; i < noutput_items; i++){      if (d_nco.get_phase() < -1*M_PI/2){        optr[i] = gr_complex(d_ampl*d_nco.get_phase()/(2*M_PI) + d_ampl/2,           d_ampl*d_nco.get_phase()/(2*M_PI) + 5*d_ampl/4)+d_offset;      }      else{        optr[i] = gr_complex(d_ampl*d_nco.get_phase()/(2*M_PI) + d_ampl/2,          d_ampl*d_nco.get_phase()/(2*M_PI) + d_ampl/4)+d_offset;      }      d_nco.step();    }      break;#else			// nope...  case GR_CONST_WAVE:    t = (@TYPE@) d_ampl + d_offset;    for (int i = 0; i < noutput_items; i++)	// FIXME unroll      optr[i] = t;    break;      case GR_SIN_WAVE:    d_nco.sin (optr, noutput_items, d_ampl);    if (d_offset == 0)      break;    for (int i = 0; i < noutput_items; i++){      optr[i] += d_offset;    }    break;  case GR_COS_WAVE:    d_nco.cos (optr, noutput_items, d_ampl);    if (d_offset == 0)      break;    for (int i = 0; i < noutput_items; i++){      optr[i] += d_offset;    }    break;     /* The square wave is high from -PI to 0.	*/   case GR_SQR_WAVE:		    t = (@TYPE@) d_ampl + d_offset;    for (int i = 0; i < noutput_items; i++){      if (d_nco.get_phase() < 0)        optr[i] = t;      else        optr[i] = d_offset;      d_nco.step();    }    break;	  /* The triangle wave rises from -PI to 0 and falls from 0 to PI.	*/   case GR_TRI_WAVE:	    for (int i = 0; i < noutput_items; i++){      double t = d_ampl*d_nco.get_phase()/M_PI;      if (d_nco.get_phase() < 0)	optr[i] = static_cast<@TYPE@>(t + d_ampl + d_offset);      else	optr[i] = static_cast<@TYPE@>(-1*t + d_ampl + d_offset);      d_nco.step();    }    break;	  /* The saw tooth wave rises from -PI to PI.	*/  case GR_SAW_WAVE:	    for (int i = 0; i < noutput_items; i++){      t = static_cast<@TYPE@>(d_ampl*d_nco.get_phase()/(2*M_PI) + d_ampl/2 + d_offset);      optr[i] = t;	   	      d_nco.step();    }    break;#endif  default:    throw std::runtime_error ("gr_sig_source: invalid waveform");  }  return noutput_items;}void@NAME@::set_sampling_freq (double sampling_freq){  d_sampling_freq = sampling_freq;  d_nco.set_freq (2 * M_PI * d_frequency / d_sampling_freq);}void@NAME@::set_waveform (gr_waveform_t waveform){  d_waveform = waveform;}void@NAME@::set_frequency (double frequency){  d_frequency = frequency;  d_nco.set_freq (2 * M_PI * d_frequency / d_sampling_freq);}void@NAME@::set_amplitude (double ampl){  d_ampl = ampl;}void@NAME@::set_offset (@TYPE@ offset){  d_offset = offset;}

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