qzdoom/dumb/src/helpers/resample.c

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/* _______ ____ __ ___ ___
* \ _ \ \ / \ / \ \ / / ' ' '
* | | \ \ | | || | \/ | . .
* | | | | | | || ||\ /| |
* | | | | | | || || \/ | | ' ' '
* | | | | | | || || | | . .
* | |_/ / \ \__// || | |
* /_______/ynamic \____/niversal /__\ /____\usic /| . . ibliotheque
* / \
* / . \
* resample.c - Resampling helpers. / / \ \
* | < / \_
* By Bob and entheh. | \/ /\ /
* \_ / > /
* In order to find a good trade-off between | \ / /
* speed and accuracy in this code, some tests | ' /
* were carried out regarding the behaviour of \__/
* int32 int32 ints with gcc. The following code
* was tested:
*
* int a, b, c;
* c = ((int32 int32)a * b) >> 16;
*
* DJGPP GCC Version 3.0.3 generated the following assembly language code for
* the multiplication and scaling, leaving the 32-bit result in EAX.
*
* movl -8(%ebp), %eax ; read one int into EAX
* imull -4(%ebp) ; multiply by the other; result goes in EDX:EAX
* shrdl $16, %edx, %eax ; shift EAX right 16, shifting bits in from EDX
*
* Note that a 32*32->64 multiplication is performed, allowing for high
* accuracy. On the Pentium 2 and above, shrdl takes two cycles (generally),
* so it is a minor concern when four multiplications are being performed
* (the cubic resampler). On the Pentium MMX and earlier, it takes four or
* more cycles, so this method is unsuitable for use in the low-quality
* resamplers.
*
* Since "int32 int32" is a gcc-specific extension, we use LONG_LONG instead,
* defined in dumb.h. We may investigate later what code MSVC generates, but
* if it seems too slow then we suggest you use a good compiler.
*
* FIXME: these comments are somewhat out of date now.
*/
#include <math.h>
#include "dumb.h"
/* Compile with -DHEAVYDEBUG if you want to make sure the pick-up function is
* called when it should be. There will be a considerable performance hit,
* since at least one condition has to be tested for every sample generated.
*/
#ifdef HEAVYDEBUG
#define HEAVYASSERT(cond) ASSERT(cond)
#else
#define HEAVYASSERT(cond)
#endif
/* Make MSVC shut the hell up about if ( upd ) UPDATE_VOLUME() conditions being constant */
#ifdef _MSC_VER
#pragma warning(disable:4127 4701)
#endif
/* A global variable for controlling resampling quality wherever a local
* specification doesn't override it. The following values are valid:
*
* 0 - DUMB_RQ_ALIASING - fastest
* 1 - DUMB_RQ_LINEAR
* 2 - DUMB_RQ_CUBIC - nicest
*
* Values outside the range 0-2 will behave the same as the nearest
* value within the range.
*/
int dumb_resampling_quality = DUMB_RQ_CUBIC;
//#define MULSC(a, b) ((int)((LONG_LONG)(a) * (b) >> 16))
//#define MULSC(a, b) ((a) * ((b) >> 2) >> 14)
#define MULSCV(a, b) ((int)((LONG_LONG)(a) * (b) >> 32))
#define MULSC(a, b) ((int)((LONG_LONG)((a) << 4) * ((b) << 12) >> 32))
#define MULSC16(a, b) ((int)((LONG_LONG)((a) << 12) * ((b) << 12) >> 32))
/* Executes the content 'iterator' times.
* Clobbers the 'iterator' variable.
* The loop is unrolled by four.
*/
#if 0
#define LOOP4(iterator, CONTENT) \
{ \
if ((iterator) & 2) { \
CONTENT; \
CONTENT; \
} \
if ((iterator) & 1) { \
CONTENT; \
} \
(iterator) >>= 2; \
while (iterator) { \
CONTENT; \
CONTENT; \
CONTENT; \
CONTENT; \
(iterator)--; \
} \
}
#else
/* [RH] Unrolling this makes the object code ~2.5x larger with
* marginal, if any, improvement in performance.
*/
#define LOOP4(iterator, CONTENT) \
{ \
while ( (iterator)-- ) \
{ \
CONTENT; \
} \
}
#endif
#define PASTERAW(a, b) a ## b /* This does not expand macros in b ... */
#define PASTE(a, b) PASTERAW(a, b) /* ... but b is expanded during this substitution. */
#define X PASTE(x.x, SRCBITS)
/* Cubic resampler: look-up tables
*
* a = 1.5*x1 - 1.5*x2 + 0.5*x3 - 0.5*x0
* b = 2*x2 + x0 - 2.5*x1 - 0.5*x3
* c = 0.5*x2 - 0.5*x0
* d = x1
*
* x = a*t*t*t + b*t*t + c*t + d
* = (-0.5*x0 + 1.5*x1 - 1.5*x2 + 0.5*x3) * t*t*t +
* ( 1*x0 - 2.5*x1 + 2 *x2 - 0.5*x3) * t*t +
* (-0.5*x0 + 0.5*x2 ) * t +
* ( 1*x1 )
* = (-0.5*t*t*t + 1 *t*t - 0.5*t ) * x0 +
* ( 1.5*t*t*t - 2.5*t*t + 1) * x1 +
* (-1.5*t*t*t + 2 *t*t + 0.5*t ) * x2 +
* ( 0.5*t*t*t - 0.5*t*t ) * x3
* = A0(t) * x0 + A1(t) * x1 + A2(t) * x2 + A3(t) * x3
*
* A0, A1, A2 and A3 stay within the range [-1,1].
* In the tables, they are scaled with 14 fractional bits.
*
* Turns out we don't need to store A2 and A3; they are symmetrical to A1 and A0.
*
* TODO: A0 and A3 stay very small indeed. Consider different scale/resolution?
*/
static short cubicA0[1025], cubicA1[1025];
static void init_cubic(void)
{
unsigned int t; /* 3*1024*1024*1024 is within range if it's unsigned */
static int done = 0;
if (done) return;
done = 1;
for (t = 0; t < 1025; t++) {
/* int casts to pacify warnings about negating unsigned values */
cubicA0[t] = -(int)( t*t*t >> 17) + (int)( t*t >> 6) - (int)(t << 3);
cubicA1[t] = (int)(3*t*t*t >> 17) - (int)(5*t*t >> 7) + (int)(1 << 14);
}
}
/* Create resamplers for 24-in-32-bit source samples. */
/* #define SUFFIX
* MSVC warns if we try to paste a null SUFFIX, so instead we define
* special macros for the function names that don't bother doing the
* corresponding paste. The more generic definitions are further down.
*/
#define process_pickup PASTE(process_pickup, SUFFIX2)
#define dumb_resample PASTE(PASTE(dumb_resample, SUFFIX2), SUFFIX3)
#define dumb_resample_get_current_sample PASTE(PASTE(dumb_resample_get_current_sample, SUFFIX2), SUFFIX3)
#define SRCTYPE sample_t
#define SRCBITS 24
#define ALIAS(x) (x >> 8)
#define LINEAR(x0, x1) (x0 + MULSC(x1 - x0, subpos))
/*
#define SET_CUBIC_COEFFICIENTS(x0, x1, x2, x3) { \
a = (3 * (x1 - x2) + (x3 - x0)) >> 1; \
b = ((x2 << 2) + (x0 << 1) - (5 * x1 + x3)) >> 1; \
c = (x2 - x0) >> 1; \
}
#define CUBIC(d) MULSC(MULSC(MULSC(MULSC(a, subpos) + b, subpos) + c, subpos) + d, vol)
*/
#define CUBIC(x0, x1, x2, x3) ( \
MULSC(x0, cubicA0[subpos >> 6] << 2) + \
MULSC(x1, cubicA1[subpos >> 6] << 2) + \
MULSC(x2, cubicA1[1 + (subpos >> 6 ^ 1023)] << 2) + \
MULSC(x3, cubicA0[1 + (subpos >> 6 ^ 1023)] << 2))
#define CUBICVOL(x, vol) MULSC(x, vol)
#include "resample.inc"
/* Undefine the simplified macros. */
#undef dumb_resample_get_current_sample
#undef dumb_resample
#undef process_pickup
/* Now define the proper ones that use SUFFIX. */
#define dumb_reset_resampler PASTE(dumb_reset_resampler, SUFFIX)
#define dumb_start_resampler PASTE(dumb_start_resampler, SUFFIX)
#define process_pickup PASTE(PASTE(process_pickup, SUFFIX), SUFFIX2)
#define dumb_resample PASTE(PASTE(PASTE(dumb_resample, SUFFIX), SUFFIX2), SUFFIX3)
#define dumb_resample_get_current_sample PASTE(PASTE(PASTE(dumb_resample_get_current_sample, SUFFIX), SUFFIX2), SUFFIX3)
#define dumb_end_resampler PASTE(dumb_end_resampler, SUFFIX)
/* Create resamplers for 16-bit source samples. */
#define SUFFIX _16
#define SRCTYPE short
#define SRCBITS 16
#define ALIAS(x) (x)
#define LINEAR(x0, x1) ((x0 << 8) + MULSC16(x1 - x0, subpos))
/*
#define SET_CUBIC_COEFFICIENTS(x0, x1, x2, x3) { \
a = (3 * (x1 - x2) + (x3 - x0)) << 7; \
b = ((x2 << 2) + (x0 << 1) - (5 * x1 + x3)) << 7; \
c = (x2 - x0) << 7; \
}
#define CUBIC(d) MULSC(MULSC(MULSC(MULSC(a, subpos) + b, subpos) + c, subpos) + (d << 8), vol)
*/
#define CUBIC(x0, x1, x2, x3) ( \
x0 * cubicA0[subpos >> 6] + \
x1 * cubicA1[subpos >> 6] + \
x2 * cubicA1[1 + (subpos >> 6 ^ 1023)] + \
x3 * cubicA0[1 + (subpos >> 6 ^ 1023)])
#define CUBICVOL(x, vol) (int)((LONG_LONG)(x) * (vol << 10) >> 32)
#include "resample.inc"
/* Create resamplers for 8-bit source samples. */
#define SUFFIX _8
#define SRCTYPE signed char
#define SRCBITS 8
#define ALIAS(x) (x << 8)
#define LINEAR(x0, x1) ((x0 << 16) + (x1 - x0) * subpos)
/*
#define SET_CUBIC_COEFFICIENTS(x0, x1, x2, x3) { \
a = 3 * (x1 - x2) + (x3 - x0); \
b = ((x2 << 2) + (x0 << 1) - (5 * x1 + x3)) << 15; \
c = (x2 - x0) << 15; \
}
#define CUBIC(d) MULSC(MULSC(MULSC((a * subpos >> 1) + b, subpos) + c, subpos) + (d << 16), vol)
*/
#define CUBIC(x0, x1, x2, x3) (( \
x0 * cubicA0[subpos >> 6] + \
x1 * cubicA1[subpos >> 6] + \
x2 * cubicA1[1 + (subpos >> 6 ^ 1023)] + \
x3 * cubicA0[1 + (subpos >> 6 ^ 1023)]) << 6)
#define CUBICVOL(x, vol) (int)((LONG_LONG)(x) * (vol << 12) >> 32)
#include "resample.inc"
#undef dumb_reset_resampler
#undef dumb_start_resampler
#undef process_pickup
#undef dumb_resample
#undef dumb_resample_get_current_sample
#undef dumb_end_resampler
void dumb_reset_resampler_n(int n, DUMB_RESAMPLER *resampler, void *src, int src_channels, int32 pos, int32 start, int32 end, int quality)
{
if (n == 8)
dumb_reset_resampler_8(resampler, src, src_channels, pos, start, end, quality);
else if (n == 16)
dumb_reset_resampler_16(resampler, src, src_channels, pos, start, end, quality);
else
dumb_reset_resampler(resampler, src, src_channels, pos, start, end, quality);
}
DUMB_RESAMPLER *dumb_start_resampler_n(int n, void *src, int src_channels, int32 pos, int32 start, int32 end, int quality)
{
if (n == 8)
return dumb_start_resampler_8(src, src_channels, pos, start, end, quality);
else if (n == 16)
return dumb_start_resampler_16(src, src_channels, pos, start, end, quality);
else
return dumb_start_resampler(src, src_channels, pos, start, end, quality);
}
#if 0
int32 dumb_resample_n_1_1(int n, DUMB_RESAMPLER *resampler, sample_t *dst, int32 dst_size, DUMB_VOLUME_RAMP_INFO * volume, double delta)
{
if (n == 8)
return dumb_resample_8_1_1(resampler, dst, dst_size, volume, delta);
else if (n == 16)
return dumb_resample_16_1_1(resampler, dst, dst_size, volume, delta);
else
return dumb_resample_1_1(resampler, dst, dst_size, volume, delta);
}
#endif
int32 dumb_resample_n_1_2(int n, DUMB_RESAMPLER *resampler, sample_t *dst, int32 dst_size, DUMB_VOLUME_RAMP_INFO * volume_left, DUMB_VOLUME_RAMP_INFO * volume_right, double delta)
{
if (n == 8)
return dumb_resample_8_1_2(resampler, dst, dst_size, volume_left, volume_right, delta);
else if (n == 16)
return dumb_resample_16_1_2(resampler, dst, dst_size, volume_left, volume_right, delta);
else
return dumb_resample_1_2(resampler, dst, dst_size, volume_left, volume_right, delta);
}
#if 0
int32 dumb_resample_n_2_1(int n, DUMB_RESAMPLER *resampler, sample_t *dst, int32 dst_size, DUMB_VOLUME_RAMP_INFO * volume_left, DUMB_VOLUME_RAMP_INFO * volume_right, double delta)
{
if (n == 8)
return dumb_resample_8_2_1(resampler, dst, dst_size, volume_left, volume_right, delta);
else if (n == 16)
return dumb_resample_16_2_1(resampler, dst, dst_size, volume_left, volume_right, delta);
else
return dumb_resample_2_1(resampler, dst, dst_size, volume_left, volume_right, delta);
}
#endif
int32 dumb_resample_n_2_2(int n, DUMB_RESAMPLER *resampler, sample_t *dst, int32 dst_size, DUMB_VOLUME_RAMP_INFO * volume_left, DUMB_VOLUME_RAMP_INFO * volume_right, double delta)
{
if (n == 8)
return dumb_resample_8_2_2(resampler, dst, dst_size, volume_left, volume_right, delta);
else if (n == 16)
return dumb_resample_16_2_2(resampler, dst, dst_size, volume_left, volume_right, delta);
else
return dumb_resample_2_2(resampler, dst, dst_size, volume_left, volume_right, delta);
}
#if 0
void dumb_resample_get_current_sample_n_1_1(int n, DUMB_RESAMPLER *resampler, DUMB_VOLUME_RAMP_INFO * volume, sample_t *dst)
{
if (n == 8)
dumb_resample_get_current_sample_8_1_1(resampler, volume, dst);
else if (n == 16)
dumb_resample_get_current_sample_16_1_1(resampler, volume, dst);
else
dumb_resample_get_current_sample_1_1(resampler, volume, dst);
}
#endif
void dumb_resample_get_current_sample_n_1_2(int n, DUMB_RESAMPLER *resampler, DUMB_VOLUME_RAMP_INFO * volume_left, DUMB_VOLUME_RAMP_INFO * volume_right, sample_t *dst)
{
if (n == 8)
dumb_resample_get_current_sample_8_1_2(resampler, volume_left, volume_right, dst);
else if (n == 16)
dumb_resample_get_current_sample_16_1_2(resampler, volume_left, volume_right, dst);
else
dumb_resample_get_current_sample_1_2(resampler, volume_left, volume_right, dst);
}
#if 0
void dumb_resample_get_current_sample_n_2_1(int n, DUMB_RESAMPLER *resampler, DUMB_VOLUME_RAMP_INFO * volume_left, DUMB_VOLUME_RAMP_INFO * volume_right, sample_t *dst)
{
if (n == 8)
dumb_resample_get_current_sample_8_2_1(resampler, volume_left, volume_right, dst);
else if (n == 16)
dumb_resample_get_current_sample_16_2_1(resampler, volume_left, volume_right, dst);
else
dumb_resample_get_current_sample_2_1(resampler, volume_left, volume_right, dst);
}
#endif
void dumb_resample_get_current_sample_n_2_2(int n, DUMB_RESAMPLER *resampler, DUMB_VOLUME_RAMP_INFO * volume_left, DUMB_VOLUME_RAMP_INFO * volume_right, sample_t *dst)
{
if (n == 8)
dumb_resample_get_current_sample_8_2_2(resampler, volume_left, volume_right, dst);
else if (n == 16)
dumb_resample_get_current_sample_16_2_2(resampler, volume_left, volume_right, dst);
else
dumb_resample_get_current_sample_2_2(resampler, volume_left, volume_right, dst);
}
void dumb_end_resampler_n(int n, DUMB_RESAMPLER *resampler)
{
if (n == 8)
dumb_end_resampler_8(resampler);
else if (n == 16)
dumb_end_resampler_16(resampler);
else
dumb_end_resampler(resampler);
}