sublay1.cpp

TMS320C6000 DSP实用技术与开发案例（书号：17481）源程序

/*  sublay1.cpp

    Implementation of layer I subband objects */

/*
 *  @(#) subband_layer_1.cc 1.7, last edit: 6/15/94 16:51:49
 *  @(#) Copyright (C) 1993, 1994 Tobias Bading (bading@cs.tu-berlin.de)
 *  @(#) Berlin University of Technology
 *
 *  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 2 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, write to the Free Software
 *  Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
 */

/*
 *  Changes from version 1.1 to 1.2:
 *    - scalefactors itself instead of scalefactor indices are stored in
 *      SubbandLayer1... objects
 *    - check for small values in [-1.0E-7, 1.0E-7] removed, because the
 *      test itself was slower than some SynthesisFilter::input_sample() calls
 *    - check for illegal scalefactor index 63 removed
 */

#include "sublay1.h"
#include "scalfact.h"

#ifdef __WIN32__
#pragma warning (disable: 4305)
#endif


// factors and offsets for sample requantization:
static const real table_factor[15] = {
  0.0f, (1.0f/2.0f) * (4.0f/3.0f), (1.0f/4.0f) * (8.0f/7.0f), (1.0f/8.0f) * (16.0f/15.0f),
  (1.0f/16.0f) * (32.0f/31.0f), (1.0f/32.0f) * (64.0f/63.0f), (1.0f/64.0f) * (128.0f/127.0f),
  (1.0f/128.0f) * (256.0f/255.0f), (1.0f/256.0f) * (512.0f/511.0f),
  (1.0f/512.0f) * (1024.0f/1023.0f), (1.0f/1024.0f) * (2048.0f/2047.0f),
  (1.0f/2048.0f) * (4096.0f/4095.0f), (1.0f/4096.0f) * (8192.0f/8191.0f),
  (1.0f/8192.0f) * (16384.0f/16383.0f), (1.0f/16384.0f) * (32768.0f/32767.0f)
};

static const real table_offset[15] = {
  0.0f, ((1.0f/2.0f)-1.0f) * (4.0f/3.0f), ((1.0f/4.0f)-1.0f) * (8.0f/7.0f), ((1.0f/8.0f)-1.0f) * (16.0f/15.0f),
  ((1.0f/16.0f)-1.0f) * (32.0f/31.0f), ((1.0f/32.0f)-1.0f) * (64.0f/63.0f), ((1.0f/64.0f)-1.0f) * (128.0f/127.0f),
  ((1.0f/128.0f)-1.0f) * (256.0f/255.0f), ((1.0f/256.0f)-1.0f) * (512.0f/511.0f),
  ((1.0f/512.0f)-1.0f) * (1024.0f/1023.0f), ((1.0f/1024.0f)-1.0f) * (2048.0f/2047.0f),
  ((1.0f/2048.0f)-1.0f) * (4096.0f/4095.0f), ((1.0f/4096.0f)-1.0f) * (8192.0f/8191.0f),
  ((1.0f/8192.0f)-1.0f) * (16384.0f/16383.0f), ((1.0f/16384.0f)-1.0f) * (32768.0f/32767.0f)
};

/**********************/	// used for single channel mode
/*** Standard Class ***/	// and in derived class for intensity
/**********************/	// stereo mode

SubbandLayer1::SubbandLayer1 (uint32 subbandnumber)
{
  this->subbandnumber = subbandnumber;
  samplenumber = 0;
}


void SubbandLayer1::read_allocation (Ibitstream *stream, Header *, Crc16 *crc)
{
  if ((allocation = stream->get_bits (4)) == 15) ;
//	 cerr << "WARNING: stream contains an illegal allocation!\n";	// MPEG-stream is corrupted!

  if (crc)
	 crc->add_bits (allocation, 4);
  if (allocation)
  {
	 samplelength = allocation + 1;
	 factor = table_factor[allocation];
    offset = table_offset[allocation];
  }
}


void SubbandLayer1::read_scalefactor (Ibitstream *stream, Header *)
{
  if (allocation)
	 scalefactor = scalefactors[stream->get_bits (6)];
}


bool SubbandLayer1::read_sampledata (Ibitstream *stream)
{
  if (allocation)
  {
	 sample = real (stream->get_bits (samplelength));
  }
  if (++samplenumber == 12)
  {
	 samplenumber = 0;
	 return true;
  }
  return false;
}


bool SubbandLayer1::put_next_sample (e_channels channels,
					  SynthesisFilter *filter1, SynthesisFilter *)
{
  if (allocation && channels != right)
  {
	 register real scaled_sample = (sample * factor + offset) * scalefactor;
	 filter1->input_sample (scaled_sample, subbandnumber);
  }
  return true;
}


/******************************/
/*** Intensity Stereo Class ***/
/******************************/

SubbandLayer1IntensityStereo::SubbandLayer1IntensityStereo (uint32 subbandnumber)
: SubbandLayer1 (subbandnumber)
{
}


void SubbandLayer1IntensityStereo::read_scalefactor (Ibitstream *stream, Header *)
{
  if (allocation)
  {
	 scalefactor = scalefactors[stream->get_bits (6)];
	 channel2_scalefactor = scalefactors[stream->get_bits (6)];
  }
}


bool SubbandLayer1IntensityStereo::put_next_sample (e_channels channels,
	SynthesisFilter *filter1, SynthesisFilter *filter2)
{
  if (allocation)
  {
    sample = sample * factor + offset;		// requantization
	 if (channels == both)
    {
		register real sample1 = sample * scalefactor,
			 sample2 = sample * channel2_scalefactor;
		filter1->input_sample (sample1, subbandnumber);
		filter2->input_sample (sample2, subbandnumber);
	 }
	 else if (channels == left)
	 {
		register real sample1 = sample * scalefactor;
		filter1->input_sample (sample1, subbandnumber);
	 }
	 else
	 {
		register real sample2 = sample * channel2_scalefactor;
		filter1->input_sample (sample2, subbandnumber);
	 }
  }
  return true;
}



/********************/
/*** Stereo Class ***/
/********************/

SubbandLayer1Stereo::SubbandLayer1Stereo (uint32 subbandnumber)
: SubbandLayer1 (subbandnumber)
{
}


void SubbandLayer1Stereo::read_allocation (Ibitstream *stream, Header *, Crc16 *crc)
{
  allocation = stream->get_bits (4);
  channel2_allocation = stream->get_bits (4);
  if (crc)
  {
	 crc->add_bits (allocation, 4);
    crc->add_bits (channel2_allocation, 4);
  }
  if (allocation)
  {
	 samplelength = allocation + 1;
    factor = table_factor[allocation];
    offset = table_offset[allocation];
  }
  if (channel2_allocation)
  {
    channel2_samplelength = channel2_allocation + 1;
	 channel2_factor = table_factor[channel2_allocation];
	 channel2_offset = table_offset[channel2_allocation];
  }
}


void SubbandLayer1Stereo::read_scalefactor (Ibitstream *stream, Header *)
{
  if (allocation)
	 scalefactor = scalefactors[stream->get_bits (6)];
  if (channel2_allocation)
	 channel2_scalefactor = scalefactors[stream->get_bits (6)];
}


bool SubbandLayer1Stereo::read_sampledata (Ibitstream *stream)
{
  bool returnvalue = SubbandLayer1::read_sampledata (stream);
  if (channel2_allocation)
  {
	 channel2_sample = real (stream->get_bits (channel2_samplelength));
  }
  return(returnvalue);
}


bool SubbandLayer1Stereo::put_next_sample (e_channels channels,
						SynthesisFilter *filter1, SynthesisFilter *filter2)
{
  SubbandLayer1::put_next_sample (channels, filter1, filter2);
  if (channel2_allocation && channels != left)
  {
	 register float sample2 = (channel2_sample * channel2_factor + channel2_offset) *
				  channel2_scalefactor;
	 if (channels == both)
		filter2->input_sample (sample2, subbandnumber);
	 else
		filter1->input_sample (sample2, subbandnumber);
  }
  return true;
}