raze-gles/source/libxmp-lite/src/mix_all.c
hendricks266 d77d1cff29 libxmp-lite: Changes to build as C++: pointer casting
git-svn-id: https://svn.eduke32.com/eduke32@6162 1a8010ca-5511-0410-912e-c29ae57300e0
2017-06-09 06:39:59 +00:00

439 lines
11 KiB
C

/* Extended Module Player
* Copyright (C) 1996-2016 Claudio Matsuoka and Hipolito Carraro Jr
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*/
#include "common.h"
#include "virtual.h"
#include "mixer.h"
#include "precomp_lut.h"
/* Mixers
*
* To increase performance eight mixers are defined, one for each
* combination of the following parameters: interpolation, resolution
* and number of channels.
*/
#define NEAREST_NEIGHBOR() do { \
smp_in = ((int16)sptr[pos] << 8); \
} while (0)
#define NEAREST_NEIGHBOR_16BIT() do { \
smp_in = sptr[pos]; \
} while (0)
#define LINEAR_INTERP() do { \
smp_l1 = ((int16)sptr[pos] << 8); \
smp_dt = ((int16)sptr[pos + 1] << 8) - smp_l1; \
smp_in = smp_l1 + (((frac >> 1) * smp_dt) >> (SMIX_SHIFT - 1)); \
} while (0)
#define LINEAR_INTERP_16BIT() do { \
smp_l1 = sptr[pos]; \
smp_dt = sptr[pos + 1] - smp_l1; \
smp_in = smp_l1 + (((frac >> 1) * smp_dt) >> (SMIX_SHIFT - 1)); \
} while (0)
/* The following lut settings are PRECOMPUTED. If you plan on changing these
* settings, you MUST also regenerate the arrays.
*/
/* number of bits used to scale spline coefs */
#define SPLINE_QUANTBITS 14
#define SPLINE_SHIFT (SPLINE_QUANTBITS)
/* log2(number) of precalculated splines (range is [4..14]) */
#define SPLINE_FRACBITS 10
#define SPLINE_LUTLEN (1L<<SPLINE_FRACBITS)
#define SPLINE_FRACSHIFT ((16 - SPLINE_FRACBITS) - 2)
#define SPLINE_FRACMASK (((1L << (16 - SPLINE_FRACSHIFT)) - 1) & ~3)
#define SPLINE_INTERP() do { \
int f = frac >> 6; \
smp_in = (cubic_spline_lut0[f] * sptr[(int)pos - 1] + \
cubic_spline_lut1[f] * sptr[pos ] + \
cubic_spline_lut3[f] * sptr[pos + 2] + \
cubic_spline_lut2[f] * sptr[pos + 1]) >> (SPLINE_SHIFT - 8); \
} while (0)
#define SPLINE_INTERP_16BIT() do { \
int f = frac >> 6; \
smp_in = (cubic_spline_lut0[f] * sptr[(int)pos - 1] + \
cubic_spline_lut1[f] * sptr[pos ] + \
cubic_spline_lut3[f] * sptr[pos + 2] + \
cubic_spline_lut2[f] * sptr[pos + 1]) >> SPLINE_SHIFT; \
} while (0)
#define LOOP_AC for (; count > ramp; count--)
#define LOOP for (; count; count--)
#define UPDATE_POS() do { \
frac += step; \
pos += frac >> SMIX_SHIFT; \
frac &= SMIX_MASK; \
} while (0)
#define MIX_MONO() do { \
*(buffer++) += smp_in * vl; \
} while (0)
#define MIX_MONO_AC() do { \
*(buffer++) += smp_in * (old_vl >> 8); old_vl += delta_l; \
} while (0)
#define MIX_MONO_FILTER() do { \
sl = (a0 * smp_in * vl + b0 * fl1 + b1 * fl2) >> FILTER_SHIFT; \
fl2 = fl1; fl1 = sl; \
*(buffer++) += sl; \
} while (0)
#define MIX_MONO_FILTER_AC() do { \
int vl = old_vl >> 8; \
MIX_MONO_FILTER(); \
old_vl += delta_l; \
} while (0)
#define MIX_STEREO() do { \
*(buffer++) += smp_in * vr; \
*(buffer++) += smp_in * vl; \
} while (0)
#define MIX_STEREO_AC() do { \
*(buffer++) += smp_in * (old_vr >> 8); old_vr += delta_r; \
*(buffer++) += smp_in * (old_vl >> 8); old_vl += delta_l; \
} while (0)
#define MIX_STEREO_FILTER() do { \
sr = (a0 * smp_in * vr + b0 * fr1 + b1 * fr2) >> FILTER_SHIFT; \
fr2 = fr1; fr1 = sr; \
sl = (a0 * smp_in * vl + b0 * fl1 + b1 * fl2) >> FILTER_SHIFT; \
fl2 = fl1; fl1 = sl; \
*(buffer++) += sr; \
*(buffer++) += sl; \
} while (0)
#define MIX_STEREO_FILTER_AC() do { \
int vr = old_vr >> 8; \
int vl = old_vl >> 8; \
MIX_STEREO_FILTER(); \
old_vr += delta_r; \
old_vl += delta_l; \
} while (0)
#define MIX_STEREO_FILTER_AC() do { \
int vr = old_vr >> 8; \
int vl = old_vl >> 8; \
MIX_STEREO_FILTER(); \
old_vr += delta_r; \
old_vl += delta_l; \
} while (0)
#define VAR_NORM(x) \
register int smp_in; \
x *sptr = (x *)vi->sptr; \
unsigned int pos = vi->pos; \
int frac = (1 << SMIX_SHIFT) * (vi->pos - (int)vi->pos)
#define VAR_LINEAR_MONO(x) \
VAR_NORM(x); \
int old_vl = vi->old_vl; \
int smp_l1, smp_dt
#define VAR_LINEAR_STEREO(x) \
VAR_LINEAR_MONO(x); \
int old_vr = vi->old_vr
#define VAR_SPLINE_MONO(x) \
int old_vl = vi->old_vl; \
VAR_NORM(x)
#define VAR_SPLINE_STEREO(x) \
VAR_SPLINE_MONO(x); \
int old_vr = vi->old_vr
#ifndef LIBXMP_CORE_DISABLE_IT
#define VAR_FILTER_MONO \
int fl1 = vi->filter.l1, fl2 = vi->filter.l2; \
int64 a0 = vi->filter.a0, b0 = vi->filter.b0, b1 = vi->filter.b1; \
int sl
#define VAR_FILTER_STEREO \
VAR_FILTER_MONO; \
int fr1 = vi->filter.r1, fr2 = vi->filter.r2; \
int sr
#define SAVE_FILTER_MONO() do { \
vi->filter.l1 = fl1; \
vi->filter.l2 = fl2; \
} while (0)
#define SAVE_FILTER_STEREO() do { \
SAVE_FILTER_MONO(); \
vi->filter.r1 = fr1; \
vi->filter.r2 = fr2; \
} while (0)
#endif
/*
* Nearest neighbor mixers
*/
/* Handler for 8 bit samples, nearest neighbor mono output
*/
MIXER(mono_8bit_nearest)
{
VAR_NORM(int8);
LOOP { NEAREST_NEIGHBOR(); MIX_MONO(); UPDATE_POS(); }
}
/* Handler for 16 bit samples, nearest neighbor mono output
*/
MIXER(mono_16bit_nearest)
{
VAR_NORM(int16);
LOOP { NEAREST_NEIGHBOR_16BIT(); MIX_MONO(); UPDATE_POS(); }
}
/* Handler for 8 bit samples, nearest neighbor stereo output
*/
MIXER(stereo_8bit_nearest)
{
VAR_NORM(int8);
LOOP { NEAREST_NEIGHBOR(); MIX_STEREO(); UPDATE_POS(); }
}
/* Handler for 16 bit samples, nearest neighbor stereo output
*/
MIXER(stereo_16bit_nearest)
{
VAR_NORM(int16);
LOOP { NEAREST_NEIGHBOR_16BIT(); MIX_STEREO(); UPDATE_POS(); }
}
/*
* Linear mixers
*/
/* Handler for 8 bit samples, linear interpolated mono output
*/
MIXER(mono_8bit_linear)
{
VAR_LINEAR_MONO(int8);
LOOP_AC { LINEAR_INTERP(); MIX_MONO_AC(); UPDATE_POS(); }
LOOP { LINEAR_INTERP(); MIX_MONO(); UPDATE_POS(); }
}
/* Handler for 16 bit samples, linear interpolated mono output
*/
MIXER(mono_16bit_linear)
{
VAR_LINEAR_MONO(int16);
LOOP_AC { LINEAR_INTERP_16BIT(); MIX_MONO_AC(); UPDATE_POS(); }
LOOP { LINEAR_INTERP_16BIT(); MIX_MONO(); UPDATE_POS(); }
}
/* Handler for 8 bit samples, linear interpolated stereo output
*/
MIXER(stereo_8bit_linear)
{
VAR_LINEAR_STEREO(int8);
LOOP_AC { LINEAR_INTERP(); MIX_STEREO_AC(); UPDATE_POS(); }
LOOP { LINEAR_INTERP(); MIX_STEREO(); UPDATE_POS(); }
}
/* Handler for 16 bit samples, linear interpolated stereo output
*/
MIXER(stereo_16bit_linear)
{
VAR_LINEAR_STEREO(int16);
LOOP_AC { LINEAR_INTERP_16BIT(); MIX_STEREO_AC(); UPDATE_POS(); }
LOOP { LINEAR_INTERP_16BIT(); MIX_STEREO(); UPDATE_POS(); }
}
#ifndef LIBXMP_CORE_DISABLE_IT
/* Handler for 8 bit samples, filtered linear interpolated mono output
*/
MIXER(mono_8bit_linear_filter)
{
VAR_LINEAR_MONO(int8);
VAR_FILTER_MONO;
LOOP_AC { LINEAR_INTERP(); MIX_MONO_FILTER_AC(); UPDATE_POS(); }
LOOP { LINEAR_INTERP(); MIX_MONO_FILTER(); UPDATE_POS(); }
SAVE_FILTER_MONO();
}
/* Handler for 16 bit samples, filtered linear interpolated mono output
*/
MIXER(mono_16bit_linear_filter)
{
VAR_LINEAR_MONO(int16);
VAR_FILTER_MONO;
LOOP_AC { LINEAR_INTERP_16BIT(); MIX_MONO_FILTER_AC(); UPDATE_POS(); }
LOOP { LINEAR_INTERP_16BIT(); MIX_MONO_FILTER(); UPDATE_POS(); }
SAVE_FILTER_MONO();
}
/* Handler for 8 bit samples, filtered linear interpolated stereo output
*/
MIXER(stereo_8bit_linear_filter)
{
VAR_LINEAR_STEREO(int8);
VAR_FILTER_STEREO;
LOOP_AC { LINEAR_INTERP(); MIX_STEREO_FILTER_AC(); UPDATE_POS(); }
LOOP { LINEAR_INTERP(); MIX_STEREO_FILTER(); UPDATE_POS(); }
SAVE_FILTER_STEREO();
}
/* Handler for 16 bit samples, filtered linear interpolated stereo output
*/
MIXER(stereo_16bit_linear_filter)
{
VAR_LINEAR_STEREO(int16);
VAR_FILTER_STEREO;
LOOP_AC { LINEAR_INTERP_16BIT(); MIX_STEREO_FILTER_AC(); UPDATE_POS(); }
LOOP { LINEAR_INTERP_16BIT(); MIX_STEREO_FILTER(); UPDATE_POS(); }
SAVE_FILTER_STEREO();
}
#endif
/*
* Spline mixers
*/
/* Handler for 8 bit samples, spline interpolated mono output
*/
MIXER(mono_8bit_spline)
{
VAR_SPLINE_MONO(int8);
LOOP_AC { SPLINE_INTERP(); MIX_MONO_AC(); UPDATE_POS(); }
LOOP { SPLINE_INTERP(); MIX_MONO(); UPDATE_POS(); }
}
/* Handler for 16 bit samples, spline interpolated mono output
*/
MIXER(mono_16bit_spline)
{
VAR_SPLINE_MONO(int16);
LOOP_AC { SPLINE_INTERP_16BIT(); MIX_MONO_AC(); UPDATE_POS(); }
LOOP { SPLINE_INTERP_16BIT(); MIX_MONO(); UPDATE_POS(); }
}
/* Handler for 8 bit samples, spline interpolated stereo output
*/
MIXER(stereo_8bit_spline)
{
VAR_SPLINE_STEREO(int8);
LOOP_AC { SPLINE_INTERP(); MIX_STEREO_AC(); UPDATE_POS(); }
LOOP { SPLINE_INTERP(); MIX_STEREO(); UPDATE_POS(); }
}
/* Handler for 16 bit samples, spline interpolated stereo output
*/
MIXER(stereo_16bit_spline)
{
VAR_SPLINE_STEREO(int16);
LOOP_AC { SPLINE_INTERP_16BIT(); MIX_STEREO_AC(); UPDATE_POS(); }
LOOP { SPLINE_INTERP_16BIT(); MIX_STEREO(); UPDATE_POS(); }
}
#ifndef LIBXMP_CORE_DISABLE_IT
/* Handler for 8 bit samples, filtered spline interpolated mono output
*/
MIXER(mono_8bit_spline_filter)
{
VAR_SPLINE_MONO(int8);
VAR_FILTER_MONO;
LOOP_AC { SPLINE_INTERP(); MIX_MONO_FILTER_AC(); UPDATE_POS(); }
LOOP { SPLINE_INTERP(); MIX_MONO_FILTER(); UPDATE_POS(); }
SAVE_FILTER_MONO();
}
/* Handler for 16 bit samples, filtered spline interpolated mono output
*/
MIXER(mono_16bit_spline_filter)
{
VAR_SPLINE_MONO(int16);
VAR_FILTER_MONO;
LOOP_AC { SPLINE_INTERP_16BIT(); MIX_MONO_FILTER_AC(); UPDATE_POS(); }
LOOP { SPLINE_INTERP_16BIT(); MIX_MONO_FILTER(); UPDATE_POS(); }
SAVE_FILTER_MONO();
}
/* Handler for 8 bit samples, filtered spline interpolated stereo output
*/
MIXER(stereo_8bit_spline_filter)
{
VAR_SPLINE_STEREO(int8);
VAR_FILTER_STEREO;
LOOP_AC { SPLINE_INTERP(); MIX_STEREO_FILTER_AC(); UPDATE_POS(); }
LOOP { SPLINE_INTERP(); MIX_STEREO_FILTER(); UPDATE_POS(); }
SAVE_FILTER_STEREO();
}
/* Handler for 16 bit samples, filtered spline interpolated stereo output
*/
MIXER(stereo_16bit_spline_filter)
{
VAR_SPLINE_STEREO(int16);
VAR_FILTER_STEREO;
LOOP_AC { SPLINE_INTERP_16BIT(); MIX_STEREO_FILTER_AC(); UPDATE_POS(); }
LOOP { SPLINE_INTERP_16BIT(); MIX_STEREO_FILTER(); UPDATE_POS(); }
SAVE_FILTER_STEREO();
}
#endif