Genesis-Plus-GX/source/sound/SRC/src_linear.c

/*
** Copyright (C) 2002-2008 Erik de Castro Lopo <erikd@mega-nerd.com>
**
** 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., 59 Temple Place, Suite 330, Boston, MA 02111-1307, USA.
*/

/*
** This code is part of Secret Rabibt Code aka libsamplerate. A commercial
** use license for this code is available, please see:
**		http://www.mega-nerd.com/SRC/procedure.html
*/

#include <stdio.h>
#include <stdlib.h>
#include <string.h>

#include "config.h"
#include "float_cast.h"
#include "common.h"

static int linear_vari_process (SRC_PRIVATE *psrc, SRC_DATA *data) ;
static void linear_reset (SRC_PRIVATE *psrc) ;

/*========================================================================================
*/

#define	LINEAR_MAGIC_MARKER	MAKE_MAGIC ('l', 'i', 'n', 'e', 'a', 'r')

#define	SRC_DEBUG	0

typedef struct
{	int		linear_magic_marker ;
	int		channels ;
	int		reset ;
	long	in_count, in_used ;
	long	out_count, out_gen ;
	float	last_value [1] ;
} LINEAR_DATA ;

/*----------------------------------------------------------------------------------------
*/

static int
linear_vari_process (SRC_PRIVATE *psrc, SRC_DATA *data)
{	LINEAR_DATA *linear ;
	double		src_ratio, input_index, rem ;
	int			ch ;

	if (psrc->private_data == NULL)
		return SRC_ERR_NO_PRIVATE ;

	linear = (LINEAR_DATA*) psrc->private_data ;

	if (linear->reset)
	{	/* If we have just been reset, set the last_value data. */
		for (ch = 0 ; ch < linear->channels ; ch++)
			linear->last_value [ch] = data->data_in [ch] ;
		linear->reset = 0 ;
		} ;

	linear->in_count = data->input_frames * linear->channels ;
	linear->out_count = data->output_frames * linear->channels ;
	linear->in_used = linear->out_gen = 0 ;

	src_ratio = psrc->last_ratio ;
	input_index = psrc->last_position ;

	/* Calculate samples before first sample in input array. */
	while (input_index < 1.0 && linear->out_gen < linear->out_count)
	{
		if (linear->in_used + linear->channels * input_index > linear->in_count)
			break ;

		if (linear->out_count > 0 && fabs (psrc->last_ratio - data->src_ratio) > SRC_MIN_RATIO_DIFF)
			src_ratio = psrc->last_ratio + linear->out_gen * (data->src_ratio - psrc->last_ratio) / linear->out_count ;

		for (ch = 0 ; ch < linear->channels ; ch++)
		{	data->data_out [linear->out_gen] = (float) (linear->last_value [ch] + input_index *
										(data->data_in [ch] - linear->last_value [ch])) ;
			linear->out_gen ++ ;
			} ;

		/* Figure out the next index. */
		input_index += 1.0 / src_ratio ;
		} ;

	rem = fmod_one (input_index) ;
	linear->in_used += linear->channels * lrint (input_index - rem) ;
	input_index = rem ;

	/* Main processing loop. */
	while (linear->out_gen < linear->out_count && linear->in_used + linear->channels * input_index <= linear->in_count)
	{
		if (linear->out_count > 0 && fabs (psrc->last_ratio - data->src_ratio) > SRC_MIN_RATIO_DIFF)
			src_ratio = psrc->last_ratio + linear->out_gen * (data->src_ratio - psrc->last_ratio) / linear->out_count ;

		if (SRC_DEBUG && linear->in_used < linear->channels && input_index < 1.0)
		{	printf ("Whoops!!!!   in_used : %ld     channels : %d     input_index : %f\n", linear->in_used, linear->channels, input_index) ;
			exit (1) ;
			} ;

		for (ch = 0 ; ch < linear->channels ; ch++)
		{	data->data_out [linear->out_gen] = (float) (data->data_in [linear->in_used - linear->channels + ch] + input_index *
						(data->data_in [linear->in_used + ch] - data->data_in [linear->in_used - linear->channels + ch])) ;
			linear->out_gen ++ ;
			} ;

		/* Figure out the next index. */
		input_index += 1.0 / src_ratio ;
		rem = fmod_one (input_index) ;

		linear->in_used += linear->channels * lrint (input_index - rem) ;
		input_index = rem ;
		} ;

	if (linear->in_used > linear->in_count)
	{	input_index += (linear->in_used - linear->in_count) / linear->channels ;
		linear->in_used = linear->in_count ;
		} ;

	psrc->last_position = input_index ;

	if (linear->in_used > 0)
		for (ch = 0 ; ch < linear->channels ; ch++)
			linear->last_value [ch] = data->data_in [linear->in_used - linear->channels + ch] ;

	/* Save current ratio rather then target ratio. */
	psrc->last_ratio = src_ratio ;

	data->input_frames_used = linear->in_used / linear->channels ;
	data->output_frames_gen = linear->out_gen / linear->channels ;

	return SRC_ERR_NO_ERROR ;
} /* linear_vari_process */

/*------------------------------------------------------------------------------
*/

const char*
linear_get_name (int src_enum)
{
	if (src_enum == SRC_LINEAR)
		return "Linear Interpolator" ;

	return NULL ;
} /* linear_get_name */

const char*
linear_get_description (int src_enum)
{
	if (src_enum == SRC_LINEAR)
		return "Linear interpolator, very fast, poor quality." ;

	return NULL ;
} /* linear_get_descrition */

int
linear_set_converter (SRC_PRIVATE *psrc, int src_enum)
{	LINEAR_DATA *linear = NULL ;

	if (src_enum != SRC_LINEAR)
		return SRC_ERR_BAD_CONVERTER ;

	if (psrc->private_data != NULL)
	{	linear = (LINEAR_DATA*) psrc->private_data ;
		if (linear->linear_magic_marker != LINEAR_MAGIC_MARKER)
		{	free (psrc->private_data) ;
			psrc->private_data = NULL ;
			} ;
		} ;

	if (psrc->private_data == NULL)
	{	linear = calloc (1, sizeof (*linear) + psrc->channels * sizeof (float)) ;
		if (linear == NULL)
			return SRC_ERR_MALLOC_FAILED ;
		psrc->private_data = linear ;
		} ;

	linear->linear_magic_marker = LINEAR_MAGIC_MARKER ;
	linear->channels = psrc->channels ;

	psrc->const_process = linear_vari_process ;
	psrc->vari_process = linear_vari_process ;
	psrc->reset = linear_reset ;

	linear_reset (psrc) ;

	return SRC_ERR_NO_ERROR ;
} /* linear_set_converter */

/*===================================================================================
*/

static void
linear_reset (SRC_PRIVATE *psrc)
{	LINEAR_DATA *linear = NULL ;

	linear = (LINEAR_DATA*) psrc->private_data ;
	if (linear == NULL)
		return ;

	linear->channels = psrc->channels ;
	linear->reset = 1 ;

	memset (linear->last_value, 0, sizeof (linear->last_value [0]) * linear->channels) ;
} /* linear_reset */
added libsamplerate support, improved zipped rom loading, improved SSG-EG support 2008-08-17 22:17:49 +02:00			`/*`
			`** Copyright (C) 2002-2008 Erik de Castro Lopo <erikd@mega-nerd.com>`
			`**`
			`** 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., 59 Temple Place, Suite 330, Boston, MA 02111-1307, USA.`
			`*/`

			`/*`
			`** This code is part of Secret Rabibt Code aka libsamplerate. A commercial`
			`** use license for this code is available, please see:`
			`** http://www.mega-nerd.com/SRC/procedure.html`
			`*/`

			`#include <stdio.h>`
			`#include <stdlib.h>`
			`#include <string.h>`

			`#include "config.h"`
			`#include "float_cast.h"`
			`#include "common.h"`

			`static int linear_vari_process (SRC_PRIVATE psrc, SRC_DATA data) ;`
			`static void linear_reset (SRC_PRIVATE *psrc) ;`

			`/*========================================================================================`
			`*/`

			`#define LINEAR_MAGIC_MARKER MAKE_MAGIC ('l', 'i', 'n', 'e', 'a', 'r')`

			`#define SRC_DEBUG 0`

			`typedef struct`
			`{ int linear_magic_marker ;`
			`int channels ;`
			`int reset ;`
			`long in_count, in_used ;`
			`long out_count, out_gen ;`
			`float last_value [1] ;`
			`} LINEAR_DATA ;`

			`/*----------------------------------------------------------------------------------------`
			`*/`

			`static int`
			`linear_vari_process (SRC_PRIVATE psrc, SRC_DATA data)`
			`{ LINEAR_DATA *linear ;`
			`double src_ratio, input_index, rem ;`
			`int ch ;`

			`if (psrc->private_data == NULL)`
			`return SRC_ERR_NO_PRIVATE ;`

			`linear = (LINEAR_DATA*) psrc->private_data ;`

			`if (linear->reset)`
			`{ /* If we have just been reset, set the last_value data. */`
			`for (ch = 0 ; ch < linear->channels ; ch++)`
			`linear->last_value [ch] = data->data_in [ch] ;`
			`linear->reset = 0 ;`
			`} ;`

			`linear->in_count = data->input_frames * linear->channels ;`
			`linear->out_count = data->output_frames * linear->channels ;`
			`linear->in_used = linear->out_gen = 0 ;`

			`src_ratio = psrc->last_ratio ;`
			`input_index = psrc->last_position ;`

			`/* Calculate samples before first sample in input array. */`
			`while (input_index < 1.0 && linear->out_gen < linear->out_count)`
			`{`
			`if (linear->in_used + linear->channels * input_index > linear->in_count)`
			`break ;`

			`if (linear->out_count > 0 && fabs (psrc->last_ratio - data->src_ratio) > SRC_MIN_RATIO_DIFF)`
			`src_ratio = psrc->last_ratio + linear->out_gen * (data->src_ratio - psrc->last_ratio) / linear->out_count ;`

			`for (ch = 0 ; ch < linear->channels ; ch++)`
			`{ data->data_out [linear->out_gen] = (float) (linear->last_value [ch] + input_index *`
			`(data->data_in [ch] - linear->last_value [ch])) ;`
			`linear->out_gen ++ ;`
			`} ;`

			`/* Figure out the next index. */`
			`input_index += 1.0 / src_ratio ;`
			`} ;`

			`rem = fmod_one (input_index) ;`
			`linear->in_used += linear->channels * lrint (input_index - rem) ;`
			`input_index = rem ;`

			`/* Main processing loop. */`
			`while (linear->out_gen < linear->out_count && linear->in_used + linear->channels * input_index <= linear->in_count)`
			`{`
			`if (linear->out_count > 0 && fabs (psrc->last_ratio - data->src_ratio) > SRC_MIN_RATIO_DIFF)`
			`src_ratio = psrc->last_ratio + linear->out_gen * (data->src_ratio - psrc->last_ratio) / linear->out_count ;`

			`if (SRC_DEBUG && linear->in_used < linear->channels && input_index < 1.0)`
			`{ printf ("Whoops!!!! in_used : %ld channels : %d input_index : %f\n", linear->in_used, linear->channels, input_index) ;`
			`exit (1) ;`
			`} ;`

			`for (ch = 0 ; ch < linear->channels ; ch++)`
			`{ data->data_out [linear->out_gen] = (float) (data->data_in [linear->in_used - linear->channels + ch] + input_index *`
			`(data->data_in [linear->in_used + ch] - data->data_in [linear->in_used - linear->channels + ch])) ;`
			`linear->out_gen ++ ;`
			`} ;`

			`/* Figure out the next index. */`
			`input_index += 1.0 / src_ratio ;`
			`rem = fmod_one (input_index) ;`

			`linear->in_used += linear->channels * lrint (input_index - rem) ;`
			`input_index = rem ;`
			`} ;`

			`if (linear->in_used > linear->in_count)`
			`{ input_index += (linear->in_used - linear->in_count) / linear->channels ;`
			`linear->in_used = linear->in_count ;`
			`} ;`

			`psrc->last_position = input_index ;`

			`if (linear->in_used > 0)`
			`for (ch = 0 ; ch < linear->channels ; ch++)`
			`linear->last_value [ch] = data->data_in [linear->in_used - linear->channels + ch] ;`

			`/* Save current ratio rather then target ratio. */`
			`psrc->last_ratio = src_ratio ;`

			`data->input_frames_used = linear->in_used / linear->channels ;`
			`data->output_frames_gen = linear->out_gen / linear->channels ;`

			`return SRC_ERR_NO_ERROR ;`
			`} /* linear_vari_process */`

			`/*------------------------------------------------------------------------------`
			`*/`

			`const char*`
			`linear_get_name (int src_enum)`
			`{`
			`if (src_enum == SRC_LINEAR)`
			`return "Linear Interpolator" ;`

			`return NULL ;`
			`} /* linear_get_name */`

			`const char*`
			`linear_get_description (int src_enum)`
			`{`
			`if (src_enum == SRC_LINEAR)`
			`return "Linear interpolator, very fast, poor quality." ;`

			`return NULL ;`
			`} /* linear_get_descrition */`

			`int`
			`linear_set_converter (SRC_PRIVATE *psrc, int src_enum)`
			`{ LINEAR_DATA *linear = NULL ;`

			`if (src_enum != SRC_LINEAR)`
			`return SRC_ERR_BAD_CONVERTER ;`

			`if (psrc->private_data != NULL)`
			`{ linear = (LINEAR_DATA*) psrc->private_data ;`
			`if (linear->linear_magic_marker != LINEAR_MAGIC_MARKER)`
			`{ free (psrc->private_data) ;`
			`psrc->private_data = NULL ;`
			`} ;`
			`} ;`

			`if (psrc->private_data == NULL)`
			`{ linear = calloc (1, sizeof (linear) + psrc->channels sizeof (float)) ;`
			`if (linear == NULL)`
			`return SRC_ERR_MALLOC_FAILED ;`
			`psrc->private_data = linear ;`
			`} ;`

			`linear->linear_magic_marker = LINEAR_MAGIC_MARKER ;`
			`linear->channels = psrc->channels ;`

			`psrc->const_process = linear_vari_process ;`
			`psrc->vari_process = linear_vari_process ;`
			`psrc->reset = linear_reset ;`

			`linear_reset (psrc) ;`

			`return SRC_ERR_NO_ERROR ;`
			`} /* linear_set_converter */`

			`/*===================================================================================`
			`*/`

			`static void`
			`linear_reset (SRC_PRIVATE *psrc)`
			`{ LINEAR_DATA *linear = NULL ;`

			`linear = (LINEAR_DATA*) psrc->private_data ;`
			`if (linear == NULL)`
			`return ;`

			`linear->channels = psrc->channels ;`
			`linear->reset = 1 ;`

			`memset (linear->last_value, 0, sizeof (linear->last_value [0]) * linear->channels) ;`
			`} /* linear_reset */`