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Revert "Consolidate all fixed point math routines in one library (FS#10400) by Jeffrey Goode"

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git-svn-id: svn://svn.rockbox.org/rockbox/trunk@21635 a1c6a512-1295-4272-9138-f99709370657
This commit is contained in:
Maurus Cuelenaere 2009-07-04 13:17:58 +00:00
parent 861b8d8606
commit c3bc8fda80
14 changed files with 713 additions and 773 deletions
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1
apps/SOURCES
View file

@ -125,7 +125,6 @@ recorder/recording.c
#if INPUT_SRC_CAPS != 0 #if INPUT_SRC_CAPS != 0
audio_path.c audio_path.c
#endif /* INPUT_SRC_CAPS != 0 */ #endif /* INPUT_SRC_CAPS != 0 */
fixedpoint.c
pcmbuf.c pcmbuf.c
playback.c playback.c
codecs.c codecs.c

119
apps/codecs/adx.c
View file

@ -21,7 +21,6 @@
#include "codeclib.h" #include "codeclib.h"
#include "inttypes.h" #include "inttypes.h"
#include "math.h" #include "math.h"
#include "fixedpoint.h"
CODEC_HEADER CODEC_HEADER
@ -42,6 +41,124 @@ const long cutoff = 500;
static int16_t samples[WAV_CHUNK_SIZE] IBSS_ATTR; static int16_t samples[WAV_CHUNK_SIZE] IBSS_ATTR;
/* fixed point stuff from apps/plugins/lib/fixedpoint.c */
/* Inverse gain of circular cordic rotation in s0.31 format. */
static const long cordic_circular_gain = 0xb2458939; /* 0.607252929 */
/* Table of values of atan(2^-i) in 0.32 format fractions of pi where pi = 0xffffffff / 2 */
static const unsigned long atan_table[] = {
0x1fffffff, /* +0.785398163 (or pi/4) */
0x12e4051d, /* +0.463647609 */
0x09fb385b, /* +0.244978663 */
0x051111d4, /* +0.124354995 */
0x028b0d43, /* +0.062418810 */
0x0145d7e1, /* +0.031239833 */
0x00a2f61e, /* +0.015623729 */
0x00517c55, /* +0.007812341 */
0x0028be53, /* +0.003906230 */
0x00145f2e, /* +0.001953123 */
0x000a2f98, /* +0.000976562 */
0x000517cc, /* +0.000488281 */
0x00028be6, /* +0.000244141 */
0x000145f3, /* +0.000122070 */
0x0000a2f9, /* +0.000061035 */
0x0000517c, /* +0.000030518 */
0x000028be, /* +0.000015259 */
0x0000145f, /* +0.000007629 */
0x00000a2f, /* +0.000003815 */
0x00000517, /* +0.000001907 */
0x0000028b, /* +0.000000954 */
0x00000145, /* +0.000000477 */
0x000000a2, /* +0.000000238 */
0x00000051, /* +0.000000119 */
0x00000028, /* +0.000000060 */
0x00000014, /* +0.000000030 */
0x0000000a, /* +0.000000015 */
0x00000005, /* +0.000000007 */
0x00000002, /* +0.000000004 */
0x00000001, /* +0.000000002 */
0x00000000, /* +0.000000001 */
0x00000000, /* +0.000000000 */
};
/**
* Implements sin and cos using CORDIC rotation.
*
* @param phase has range from 0 to 0xffffffff, representing 0 and
* 2*pi respectively.
* @param cos return address for cos
* @return sin of phase, value is a signed value from LONG_MIN to LONG_MAX,
* representing -1 and 1 respectively.
*/
static long fsincos(unsigned long phase, long *cos)
{
int32_t x, x1, y, y1;
unsigned long z, z1;
int i;
/* Setup initial vector */
x = cordic_circular_gain;
y = 0;
z = phase;
/* The phase has to be somewhere between 0..pi for this to work right */
if (z < 0xffffffff / 4) {
/* z in first quadrant, z += pi/2 to correct */
x = -x;
z += 0xffffffff / 4;
} else if (z < 3 * (0xffffffff / 4)) {
/* z in third quadrant, z -= pi/2 to correct */
z -= 0xffffffff / 4;
} else {
/* z in fourth quadrant, z -= 3pi/2 to correct */
x = -x;
z -= 3 * (0xffffffff / 4);
}
/* Each iteration adds roughly 1-bit of extra precision */
for (i = 0; i < 31; i++) {
x1 = x >> i;
y1 = y >> i;
z1 = atan_table[i];
/* Decided which direction to rotate vector. Pivot point is pi/2 */
if (z >= 0xffffffff / 4) {
x -= y1;
y += x1;
z -= z1;
} else {
x += y1;
y -= x1;
z += z1;
}
}
if (cos)
*cos = x;
return y;
}
/**
* Fixed point square root via Newton-Raphson.
* @param a square root argument.
* @param fracbits specifies number of fractional bits in argument.
* @return Square root of argument in same fixed point format as input.
*/
static long fsqrt(long a, unsigned int fracbits)
{
long b = a/2 + (1 << fracbits); /* initial approximation */
unsigned n;
const unsigned iterations = 8; /* bumped up from 4 as it wasn't
nearly enough for 28 fractional bits */
for (n = 0; n < iterations; ++n)
b = (b + (long)(((long long)(a) << fracbits)/b))/2;
return b;
}
/* this is the codec entry point */ /* this is the codec entry point */
enum codec_status codec_main(void) enum codec_status codec_main(void)
{ {

2
apps/codecs/lib/SOURCES
View file

@ -1,6 +1,6 @@
#if CONFIG_CODEC == SWCODEC /* software codec platforms */ #if CONFIG_CODEC == SWCODEC /* software codec platforms */
codeclib.c codeclib.c
../../fixedpoint.c
mdct2.c mdct2.c
#ifdef CPU_ARM #ifdef CPU_ARM

126
apps/codecs/lib/fixedpoint.h
View file

@ -1,126 +0,0 @@
/***************************************************************************
* __________ __ ___.
* Open \______ \ ____ ____ | | _\_ |__ _______ ___
* Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ /
* Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < <
* Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \
* \/ \/ \/ \/ \/
* $Id: fixedpoint.h -1 $
*
* Copyright (C) 2006 Jens Arnold
*
* Fixed point library for plugins
*
* 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 software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY
* KIND, either express or implied.
*
****************************************************************************/
#ifndef _FIXEDPOINT_H
#define _FIXEDPOINT_H
#include <inttypes.h>
/** TAKEN FROM apps/dsp.h */
/* A bunch of fixed point assembler helper macros */
#if defined(CPU_COLDFIRE)
/* These macros use the Coldfire EMAC extension and need the MACSR flags set
* to fractional mode with no rounding.
*/
/* Multiply two S.31 fractional integers and return the sign bit and the
* 31 most significant bits of the result.
*/
#define FRACMUL(x, y) \
({ \
long t; \
asm ("mac.l %[a], %[b], %%acc0\n\t" \
"movclr.l %%acc0, %[t]\n\t" \
: [t] "=r" (t) : [a] "r" (x), [b] "r" (y)); \
t; \
})
/* Multiply two S.31 fractional integers, and return the 32 most significant
* bits after a shift left by the constant z. NOTE: Only works for shifts of
* 1 to 8 on Coldfire!
*/
#define FRACMUL_SHL(x, y, z) \
({ \
long t, t2; \
asm ("mac.l %[a], %[b], %%acc0\n\t" \
"moveq.l %[d], %[t]\n\t" \
"move.l %%accext01, %[t2]\n\t" \
"and.l %[mask], %[t2]\n\t" \
"lsr.l %[t], %[t2]\n\t" \
"movclr.l %%acc0, %[t]\n\t" \
"asl.l %[c], %[t]\n\t" \
"or.l %[t2], %[t]\n\t" \
: [t] "=&d" (t), [t2] "=&d" (t2) \
: [a] "r" (x), [b] "r" (y), [mask] "d" (0xff), \
[c] "i" ((z)), [d] "i" (8 - (z))); \
t; \
})
#elif defined(CPU_ARM)
/* Multiply two S.31 fractional integers and return the sign bit and the
* 31 most significant bits of the result.
*/
#define FRACMUL(x, y) \
({ \
long t, t2; \
asm ("smull %[t], %[t2], %[a], %[b]\n\t" \
"mov %[t2], %[t2], asl #1\n\t" \
"orr %[t], %[t2], %[t], lsr #31\n\t" \
: [t] "=&r" (t), [t2] "=&r" (t2) \
: [a] "r" (x), [b] "r" (y)); \
t; \
})
/* Multiply two S.31 fractional integers, and return the 32 most significant
* bits after a shift left by the constant z.
*/
#define FRACMUL_SHL(x, y, z) \
({ \
long t, t2; \
asm ("smull %[t], %[t2], %[a], %[b]\n\t" \
"mov %[t2], %[t2], asl %[c]\n\t" \
"orr %[t], %[t2], %[t], lsr %[d]\n\t" \
: [t] "=&r" (t), [t2] "=&r" (t2) \
: [a] "r" (x), [b] "r" (y), \
[c] "M" ((z) + 1), [d] "M" (31 - (z))); \
t; \
})
#else
#define FRACMUL(x, y) (long) (((((long long) (x)) * ((long long) (y))) >> 31))
#define FRACMUL_SHL(x, y, z) \
((long)(((((long long) (x)) * ((long long) (y))) >> (31 - (z)))))
#endif
#define DIV64(x, y, z) (long)(((long long)(x) << (z))/(y))
/** TAKEN FROM ORIGINAL fixedpoint.h */
/* fast unsigned multiplication (16x16bit->32bit or 32x32bit->32bit,
* whichever is faster for the architecture) */
#ifdef CPU_ARM
#define FMULU(a, b) ((uint32_t) (((uint32_t) (a)) * ((uint32_t) (b))))
#else /* SH1, coldfire */
#define FMULU(a, b) ((uint32_t) (((uint16_t) (a)) * ((uint16_t) (b))))
#endif
long fsincos(unsigned long phase, long *cos);
long fsqrt(long a, unsigned int fracbits);
long cos_int(int val);
long sin_int(int val);
long flog(int x);
#endif

1
apps/codecs/spc.c
View file

@ -26,7 +26,6 @@
/* DSP Based on Brad Martin's OpenSPC DSP emulator */ /* DSP Based on Brad Martin's OpenSPC DSP emulator */
/* tag reading from sexyspc by John Brawn (John_Brawn@yahoo.com) and others */ /* tag reading from sexyspc by John Brawn (John_Brawn@yahoo.com) and others */
#include "codeclib.h" #include "codeclib.h"
#include "fixedpoint.h"
#include "libspc/spc_codec.h" #include "libspc/spc_codec.h"
#include "libspc/spc_profiler.h" #include "libspc/spc_profiler.h"

1
apps/dsp.c
View file

@ -33,7 +33,6 @@
#include "misc.h" #include "misc.h"
#include "tdspeed.h" #include "tdspeed.h"
#include "buffer.h" #include "buffer.h"
#include "fixedpoint.h"
/* 16-bit samples are scaled based on these constants. The shift should be /* 16-bit samples are scaled based on these constants. The shift should be
* no more than 15. * no more than 15.

80
apps/dsp.h
View file

@ -64,6 +64,86 @@ enum {
DSP_CALLBACK_SET_STEREO_WIDTH DSP_CALLBACK_SET_STEREO_WIDTH
}; };
/* A bunch of fixed point assembler helper macros */
#if defined(CPU_COLDFIRE)
/* These macros use the Coldfire EMAC extension and need the MACSR flags set
* to fractional mode with no rounding.
*/
/* Multiply two S.31 fractional integers and return the sign bit and the
* 31 most significant bits of the result.
*/
#define FRACMUL(x, y) \
({ \
long t; \
asm ("mac.l %[a], %[b], %%acc0\n\t" \
"movclr.l %%acc0, %[t]\n\t" \
: [t] "=r" (t) : [a] "r" (x), [b] "r" (y)); \
t; \
})
/* Multiply two S.31 fractional integers, and return the 32 most significant
* bits after a shift left by the constant z. NOTE: Only works for shifts of
* 1 to 8 on Coldfire!
*/
#define FRACMUL_SHL(x, y, z) \
({ \
long t, t2; \
asm ("mac.l %[a], %[b], %%acc0\n\t" \
"moveq.l %[d], %[t]\n\t" \
"move.l %%accext01, %[t2]\n\t" \
"and.l %[mask], %[t2]\n\t" \
"lsr.l %[t], %[t2]\n\t" \
"movclr.l %%acc0, %[t]\n\t" \
"asl.l %[c], %[t]\n\t" \
"or.l %[t2], %[t]\n\t" \
: [t] "=&d" (t), [t2] "=&d" (t2) \
: [a] "r" (x), [b] "r" (y), [mask] "d" (0xff), \
[c] "i" ((z)), [d] "i" (8 - (z))); \
t; \
})
#elif defined(CPU_ARM)
/* Multiply two S.31 fractional integers and return the sign bit and the
* 31 most significant bits of the result.
*/
#define FRACMUL(x, y) \
({ \
long t, t2; \
asm ("smull %[t], %[t2], %[a], %[b]\n\t" \
"mov %[t2], %[t2], asl #1\n\t" \
"orr %[t], %[t2], %[t], lsr #31\n\t" \
: [t] "=&r" (t), [t2] "=&r" (t2) \
: [a] "r" (x), [b] "r" (y)); \
t; \
})
/* Multiply two S.31 fractional integers, and return the 32 most significant
* bits after a shift left by the constant z.
*/
#define FRACMUL_SHL(x, y, z) \
({ \
long t, t2; \
asm ("smull %[t], %[t2], %[a], %[b]\n\t" \
"mov %[t2], %[t2], asl %[c]\n\t" \
"orr %[t], %[t2], %[t], lsr %[d]\n\t" \
: [t] "=&r" (t), [t2] "=&r" (t2) \
: [a] "r" (x), [b] "r" (y), \
[c] "M" ((z) + 1), [d] "M" (31 - (z))); \
t; \
})
#else
#define FRACMUL(x, y) (long) (((((long long) (x)) * ((long long) (y))) >> 31))
#define FRACMUL_SHL(x, y, z) \
((long)(((((long long) (x)) * ((long long) (y))) >> (31 - (z)))))
#endif
#define DIV64(x, y, z) (long)(((long long)(x) << (z))/(y))
struct dsp_config; struct dsp_config;
int dsp_process(struct dsp_config *dsp, char *dest, int dsp_process(struct dsp_config *dsp, char *dest,

97
apps/eq.c
View file

@ -21,10 +21,105 @@
#include <inttypes.h> #include <inttypes.h>
#include "config.h" #include "config.h"
#include "fixedpoint.h" #include "dsp.h"
#include "eq.h" #include "eq.h"
#include "replaygain.h" #include "replaygain.h"
/* Inverse gain of circular cordic rotation in s0.31 format. */
static const long cordic_circular_gain = 0xb2458939; /* 0.607252929 */
/* Table of values of atan(2^-i) in 0.32 format fractions of pi where pi = 0xffffffff / 2 */
static const unsigned long atan_table[] = {
0x1fffffff, /* +0.785398163 (or pi/4) */
0x12e4051d, /* +0.463647609 */
0x09fb385b, /* +0.244978663 */
0x051111d4, /* +0.124354995 */
0x028b0d43, /* +0.062418810 */
0x0145d7e1, /* +0.031239833 */
0x00a2f61e, /* +0.015623729 */
0x00517c55, /* +0.007812341 */
0x0028be53, /* +0.003906230 */
0x00145f2e, /* +0.001953123 */
0x000a2f98, /* +0.000976562 */
0x000517cc, /* +0.000488281 */
0x00028be6, /* +0.000244141 */
0x000145f3, /* +0.000122070 */
0x0000a2f9, /* +0.000061035 */
0x0000517c, /* +0.000030518 */
0x000028be, /* +0.000015259 */
0x0000145f, /* +0.000007629 */
0x00000a2f, /* +0.000003815 */
0x00000517, /* +0.000001907 */
0x0000028b, /* +0.000000954 */
0x00000145, /* +0.000000477 */
0x000000a2, /* +0.000000238 */
0x00000051, /* +0.000000119 */
0x00000028, /* +0.000000060 */
0x00000014, /* +0.000000030 */
0x0000000a, /* +0.000000015 */
0x00000005, /* +0.000000007 */
0x00000002, /* +0.000000004 */
0x00000001, /* +0.000000002 */
0x00000000, /* +0.000000001 */
0x00000000, /* +0.000000000 */
};
/**
* Implements sin and cos using CORDIC rotation.
*
* @param phase has range from 0 to 0xffffffff, representing 0 and
* 2*pi respectively.
* @param cos return address for cos
* @return sin of phase, value is a signed value from LONG_MIN to LONG_MAX,
* representing -1 and 1 respectively.
*/
static long fsincos(unsigned long phase, long *cos) {
int32_t x, x1, y, y1;
unsigned long z, z1;
int i;
/* Setup initial vector */
x = cordic_circular_gain;
y = 0;
z = phase;
/* The phase has to be somewhere between 0..pi for this to work right */
if (z < 0xffffffff / 4) {
/* z in first quadrant, z += pi/2 to correct */
x = -x;
z += 0xffffffff / 4;
} else if (z < 3 * (0xffffffff / 4)) {
/* z in third quadrant, z -= pi/2 to correct */
z -= 0xffffffff / 4;
} else {
/* z in fourth quadrant, z -= 3pi/2 to correct */
x = -x;
z -= 3 * (0xffffffff / 4);
}
/* Each iteration adds roughly 1-bit of extra precision */
for (i = 0; i < 31; i++) {
x1 = x >> i;
y1 = y >> i;
z1 = atan_table[i];
/* Decided which direction to rotate vector. Pivot point is pi/2 */
if (z >= 0xffffffff / 4) {
x -= y1;
y += x1;
z -= z1;
} else {
x += y1;
y -= x1;
z += z1;
}
}
*cos = x;
return y;
}
/** /**
* Calculate first order shelving filter. Filter is not directly usable by the * Calculate first order shelving filter. Filter is not directly usable by the
* eq_filter() function. * eq_filter() function.

1
apps/eq.h
View file

@ -23,7 +23,6 @@
#define _EQ_H #define _EQ_H
#include <inttypes.h> #include <inttypes.h>
#include <stdbool.h>
/* These depend on the fixed point formats used by the different filter types /* These depend on the fixed point formats used by the different filter types
and need to be changed when they change. and need to be changed when they change.

440
apps/fixedpoint.c
View file

@ -1,440 +0,0 @@
/***************************************************************************
* __________ __ ___.
* Open \______ \ ____ ____ | | _\_ |__ _______ ___
* Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ /
* Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < <
* Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \
* \/ \/ \/ \/ \/
* $Id$
*
* Copyright (C) 2006 Jens Arnold
*
* Fixed point library for plugins
*
* 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 software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY
* KIND, either express or implied.
*
****************************************************************************/
#include "fixedpoint.h"
#include <stdlib.h>
#include <stdbool.h>
#ifndef BIT_N
#define BIT_N(n) (1U << (n))
#endif
/** TAKEN FROM ORIGINAL fixedpoint.h */
/* Inverse gain of circular cordic rotation in s0.31 format. */
static const long cordic_circular_gain = 0xb2458939; /* 0.607252929 */
/* Table of values of atan(2^-i) in 0.32 format fractions of pi where pi = 0xffffffff / 2 */
static const unsigned long atan_table[] = {
0x1fffffff, /* +0.785398163 (or pi/4) */
0x12e4051d, /* +0.463647609 */
0x09fb385b, /* +0.244978663 */
0x051111d4, /* +0.124354995 */
0x028b0d43, /* +0.062418810 */
0x0145d7e1, /* +0.031239833 */
0x00a2f61e, /* +0.015623729 */
0x00517c55, /* +0.007812341 */
0x0028be53, /* +0.003906230 */
0x00145f2e, /* +0.001953123 */
0x000a2f98, /* +0.000976562 */
0x000517cc, /* +0.000488281 */
0x00028be6, /* +0.000244141 */
0x000145f3, /* +0.000122070 */
0x0000a2f9, /* +0.000061035 */
0x0000517c, /* +0.000030518 */
0x000028be, /* +0.000015259 */
0x0000145f, /* +0.000007629 */
0x00000a2f, /* +0.000003815 */
0x00000517, /* +0.000001907 */
0x0000028b, /* +0.000000954 */
0x00000145, /* +0.000000477 */
0x000000a2, /* +0.000000238 */
0x00000051, /* +0.000000119 */
0x00000028, /* +0.000000060 */
0x00000014, /* +0.000000030 */
0x0000000a, /* +0.000000015 */
0x00000005, /* +0.000000007 */
0x00000002, /* +0.000000004 */
0x00000001, /* +0.000000002 */
0x00000000, /* +0.000000001 */
0x00000000, /* +0.000000000 */
};
/* Precalculated sine and cosine * 16384 (2^14) (fixed point 18.14) */
static const short sin_table[91] =
{
0, 285, 571, 857, 1142, 1427, 1712, 1996, 2280, 2563,
2845, 3126, 3406, 3685, 3963, 4240, 4516, 4790, 5062, 5334,
5603, 5871, 6137, 6401, 6663, 6924, 7182, 7438, 7691, 7943,
8191, 8438, 8682, 8923, 9161, 9397, 9630, 9860, 10086, 10310,
10531, 10748, 10963, 11173, 11381, 11585, 11785, 11982, 12175, 12365,
12550, 12732, 12910, 13084, 13254, 13420, 13582, 13740, 13894, 14043,
14188, 14329, 14466, 14598, 14725, 14848, 14967, 15081, 15190, 15295,
15395, 15491, 15582, 15668, 15749, 15825, 15897, 15964, 16025, 16082,
16135, 16182, 16224, 16261, 16294, 16321, 16344, 16361, 16374, 16381,
16384
};
/**
* Implements sin and cos using CORDIC rotation.
*
* @param phase has range from 0 to 0xffffffff, representing 0 and
* 2*pi respectively.
* @param cos return address for cos
* @return sin of phase, value is a signed value from LONG_MIN to LONG_MAX,
* representing -1 and 1 respectively.
*/
long fsincos(unsigned long phase, long *cos)
{
int32_t x, x1, y, y1;
unsigned long z, z1;
int i;
/* Setup initial vector */
x = cordic_circular_gain;
y = 0;
z = phase;
/* The phase has to be somewhere between 0..pi for this to work right */
if (z < 0xffffffff / 4) {
/* z in first quadrant, z += pi/2 to correct */
x = -x;
z += 0xffffffff / 4;
} else if (z < 3 * (0xffffffff / 4)) {
/* z in third quadrant, z -= pi/2 to correct */
z -= 0xffffffff / 4;
} else {
/* z in fourth quadrant, z -= 3pi/2 to correct */
x = -x;
z -= 3 * (0xffffffff / 4);
}
/* Each iteration adds roughly 1-bit of extra precision */
for (i = 0; i < 31; i++) {
x1 = x >> i;
y1 = y >> i;
z1 = atan_table[i];
/* Decided which direction to rotate vector. Pivot point is pi/2 */
if (z >= 0xffffffff / 4) {
x -= y1;
y += x1;
z -= z1;
} else {
x += y1;
y -= x1;
z += z1;
}
}
if (cos)
*cos = x;
return y;
}
/**
* Fixed point square root via Newton-Raphson.
* @param x square root argument.
* @param fracbits specifies number of fractional bits in argument.
* @return Square root of argument in same fixed point format as input.
*
* This routine has been modified to run longer for greater precision,
* but cuts calculation short if the answer is reached sooner. In
* general, the closer x is to 1, the quicker the calculation.
*/
long fsqrt(long x, unsigned int fracbits)
{
long b = x/2 + BIT_N(fracbits); /* initial approximation */
long c;
unsigned n;
const unsigned iterations = 8;
for (n = 0; n < iterations; ++n)
{
c = DIV64(x, b, fracbits);
if (c == b) break;
b = (b + c)/2;
}
return b;
}
/**
* Fixed point sinus using a lookup table
* don't forget to divide the result by 16384 to get the actual sinus value
* @param val sinus argument in degree
* @return sin(val)*16384
*/
long sin_int(int val)
{
val = (val+360)%360;
if (val < 181)
{
if (val < 91)/* phase 0-90 degree */
return (long)sin_table[val];
else/* phase 91-180 degree */
return (long)sin_table[180-val];
}
else
{
if (val < 271)/* phase 181-270 degree */
return -(long)sin_table[val-180];
else/* phase 270-359 degree */
return -(long)sin_table[360-val];
}
return 0;
}
/**
* Fixed point cosinus using a lookup table
* don't forget to divide the result by 16384 to get the actual cosinus value
* @param val sinus argument in degree
* @return cos(val)*16384
*/
long cos_int(int val)
{
val = (val+360)%360;
if (val < 181)
{
if (val < 91)/* phase 0-90 degree */
return (long)sin_table[90-val];
else/* phase 91-180 degree */
return -(long)sin_table[val-90];
}
else
{
if (val < 271)/* phase 181-270 degree */
return -(long)sin_table[270-val];
else/* phase 270-359 degree */
return (long)sin_table[val-270];
}
return 0;
}
/**
* Fixed-point natural log
* taken from http://www.quinapalus.com/efunc.html
* "The code assumes integers are at least 32 bits long. The (positive)
* argument and the result of the function are both expressed as fixed-point
* values with 16 fractional bits, although intermediates are kept with 28
* bits of precision to avoid loss of accuracy during shifts."
*/
long flog(int x) {
long t,y;
y=0xa65af;
if(x<0x00008000) x<<=16, y-=0xb1721;
if(x<0x00800000) x<<= 8, y-=0x58b91;
if(x<0x08000000) x<<= 4, y-=0x2c5c8;
if(x<0x20000000) x<<= 2, y-=0x162e4;
if(x<0x40000000) x<<= 1, y-=0x0b172;
t=x+(x>>1); if((t&0x80000000)==0) x=t,y-=0x067cd;
t=x+(x>>2); if((t&0x80000000)==0) x=t,y-=0x03920;
t=x+(x>>3); if((t&0x80000000)==0) x=t,y-=0x01e27;
t=x+(x>>4); if((t&0x80000000)==0) x=t,y-=0x00f85;
t=x+(x>>5); if((t&0x80000000)==0) x=t,y-=0x007e1;
t=x+(x>>6); if((t&0x80000000)==0) x=t,y-=0x003f8;
t=x+(x>>7); if((t&0x80000000)==0) x=t,y-=0x001fe;
x=0x80000000-x;
y-=x>>15;
return y;
}
/** MODIFIED FROM replaygain.c */
/* These math routines have 64-bit internal precision to avoid overflows.
* Arguments and return values are 32-bit (long) precision.
*/
#define FP_MUL64(x, y) (((x) * (y)) >> (fracbits))
#define FP_DIV64(x, y) (((x) << (fracbits)) / (y))
static long long fp_exp10(long long x, unsigned int fracbits);
static long long fp_log10(long long n, unsigned int fracbits);
/* constants in fixed point format, 28 fractional bits */
#define FP28_LN2 (186065279LL) /* ln(2) */
#define FP28_LN2_INV (387270501LL) /* 1/ln(2) */
#define FP28_EXP_ZERO (44739243LL) /* 1/6 */
#define FP28_EXP_ONE (-745654LL) /* -1/360 */
#define FP28_EXP_TWO (12428LL) /* 1/21600 */
#define FP28_LN10 (618095479LL) /* ln(10) */
#define FP28_LOG10OF2 (80807124LL) /* log10(2) */
#define TOL_BITS 2 /* log calculation tolerance */
/* The fpexp10 fixed point math routine is based
* on oMathFP by Dan Carter (http://orbisstudios.com).
*/
/** FIXED POINT EXP10
* Return 10^x as FP integer. Argument is FP integer.
*/
static long long fp_exp10(long long x, unsigned int fracbits)
{
long long k;
long long z;
long long R;
long long xp;
/* scale constants */
const long long fp_one = (1 << fracbits);
const long long fp_half = (1 << (fracbits - 1));
const long long fp_two = (2 << fracbits);
const long long fp_mask = (fp_one - 1);
const long long fp_ln2_inv = (FP28_LN2_INV >> (28 - fracbits));
const long long fp_ln2 = (FP28_LN2 >> (28 - fracbits));
const long long fp_ln10 = (FP28_LN10 >> (28 - fracbits));
const long long fp_exp_zero = (FP28_EXP_ZERO >> (28 - fracbits));
const long long fp_exp_one = (FP28_EXP_ONE >> (28 - fracbits));
const long long fp_exp_two = (FP28_EXP_TWO >> (28 - fracbits));
/* exp(0) = 1 */
if (x == 0)
{
return fp_one;
}
/* convert from base 10 to base e */
x = FP_MUL64(x, fp_ln10);
/* calculate exp(x) */
k = (FP_MUL64(abs(x), fp_ln2_inv) + fp_half) & ~fp_mask;
if (x < 0)
{
k = -k;
}
x -= FP_MUL64(k, fp_ln2);
z = FP_MUL64(x, x);
R = fp_two + FP_MUL64(z, fp_exp_zero + FP_MUL64(z, fp_exp_one
+ FP_MUL64(z, fp_exp_two)));
xp = fp_one + FP_DIV64(FP_MUL64(fp_two, x), R - x);
if (k < 0)
{
k = fp_one >> (-k >> fracbits);
}
else
{
k = fp_one << (k >> fracbits);
}
return FP_MUL64(k, xp);
}
/** FIXED POINT LOG10
* Return log10(x) as FP integer. Argument is FP integer.
*/
static long long fp_log10(long long n, unsigned int fracbits)
{
/* Calculate log2 of argument */
long long log2, frac;
const long long fp_one = (1 << fracbits);
const long long fp_two = (2 << fracbits);
const long tolerance = (1 << ((fracbits / 2) + 2));
if (n <=0) return FP_NEGINF;
log2 = 0;
/* integer part */
while (n < fp_one)
{
log2 -= fp_one;
n <<= 1;
}
while (n >= fp_two)
{
log2 += fp_one;
n >>= 1;
}
/* fractional part */
frac = fp_one;
while (frac > tolerance)
{
frac >>= 1;
n = FP_MUL64(n, n);
if (n >= fp_two)
{
n >>= 1;
log2 += frac;
}
}
/* convert log2 to log10 */
return FP_MUL64(log2, (FP28_LOG10OF2 >> (28 - fracbits)));
}
/** CONVERT FACTOR TO DECIBELS */
long fp_decibels(unsigned long factor, unsigned int fracbits)
{
long long decibels;
long long f = (long long)factor;
bool neg;
/* keep factor in signed long range */
if (f >= (1LL << 31))
f = (1LL << 31) - 1;
/* decibels = 20 * log10(factor) */
decibels = FP_MUL64((20LL << fracbits), fp_log10(f, fracbits));
/* keep result in signed long range */
if ((neg = (decibels < 0)))
decibels = -decibels;
if (decibels >= (1LL << 31))
return neg ? FP_NEGINF : FP_INF;
return neg ? (long)-decibels : (long)decibels;
}
/** CONVERT DECIBELS TO FACTOR */
long fp_factor(long decibels, unsigned int fracbits)
{
bool neg;
long long factor;
long long db = (long long)decibels;
/* if decibels is 0, factor is 1 */
if (db == 0)
return (1L << fracbits);
/* calculate for positive decibels only */
if ((neg = (db < 0)))
db = -db;
/* factor = 10 ^ (decibels / 20) */
factor = fp_exp10(FP_DIV64(db, (20LL << fracbits)), fracbits);
/* keep result in signed long range, return 0 if very small */
if (factor >= (1LL << 31))
{
if (neg)
return 0;
else
return FP_INF;
}
/* if negative argument, factor is 1 / result */
if (neg)
factor = FP_DIV64((1LL << fracbits), factor);
return (long)factor;
}

197
apps/fixedpoint.h
View file

@ -1,197 +0,0 @@
/***************************************************************************
* __________ __ ___.
* Open \______ \ ____ ____ | | _\_ |__ _______ ___
* Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ /
* Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < <
* Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \
* \/ \/ \/ \/ \/
* $Id$
*
* Copyright (C) 2006 Jens Arnold
*
* Fixed point library for plugins
*
* 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 software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY
* KIND, either express or implied.
*
****************************************************************************/
/** FIXED POINT MATH ROUTINES - USAGE
*
* - x and y arguments are fixed point integers
* - fracbits is the number of fractional bits in the argument(s)
* - functions return long fixed point integers with the specified number
* of fractional bits unless otherwise specified
*
* Multiply two fixed point numbers:
* fp_mul(x, y, fracbits)
*
* Shortcut: Multiply two fixed point numbers with 31 fractional bits:
* fp31_mul(x, y)
*
* Shortcut: Multiply two fixed point numbers with 31 fractional bits,
* then shift left by z bits:
* fp31_mulshl(x, y, z)
* NOTE: z must be in the range 1-8 on Coldfire targets.
*
* Divide two fixed point numbers:
* fp_div(x, y, fracbits)
*
* Take square root of a fixed point number:
* fp_sqrt(x, fracbits)
*
* Calculate sin and cos of an angle:
* fp_sincos(phase, *cos)
* where phase is a 32 bit unsigned integer with 0 representing 0
* and 0xFFFFFFFF representing 2*pi, and *cos is the address to
* a long signed integer. Value returned is a long signed integer
* from LONG_MIN to LONG_MAX, representing -1 to 1 respectively.
* That is, value is a fixed point integer with 31 fractional bits.
*
* Calculate sin or cos of an angle (very fast, from a table):
* fp14_sin(angle)
* fp14_cos(angle)
* where angle is a non-fixed point integer in degrees. Value
* returned is a fixed point integer with 14 fractional bits.
*
* Calculate decibel equivalent of a gain factor:
* fp_decibels(factor, fracbits)
* where fracbits is in the range 12 to 22 (higher is better),
* and factor is a positive fixed point integer.
*
* Calculate factor equivalent of a decibel value:
* fp_factor(decibels, fracbits)
* where fracbits is in the range 12 to 22 (lower is better),
* and decibels is a fixed point integer.
*/
#ifndef _FIXEDPOINT_H
#define _FIXEDPOINT_H
#include <inttypes.h>
/* Redefine function names, making sure legacy code is usable */
#define fp31_mul(x, y) FRACMUL(x, y)
#define fp31_mulshl(x, y, z) FRACMUL_SHL(x, y, z)
#define fp_div(x, y, z) DIV64(x, y, z)
#define fp_sqrt(x, y) fsqrt(x, y)
#define fp_sincos(x, y) fsincos(x, y)
#define fp14_sin(x) sin_int(x)
#define fp14_cos(x) cos_int(x)
#define fp16_log(x) flog(x)
#define fp_mul(x, y, z) (long)((((long long)(x)) * ((long long)(y))) >> (z))
#define DIV64(x, y, z) (long)((((long long)(x)) << (z)) / ((long long)(y)))
/** TAKEN FROM apps/dsp.h */
/* A bunch of fixed point assembler helper macros */
#if defined(CPU_COLDFIRE)
/* These macros use the Coldfire EMAC extension and need the MACSR flags set
* to fractional mode with no rounding.
*/
/* Multiply two S.31 fractional integers and return the sign bit and the
* 31 most significant bits of the result.
*/
#define FRACMUL(x, y) \
({ \
long t; \
asm ("mac.l %[a], %[b], %%acc0\n\t" \
"movclr.l %%acc0, %[t]\n\t" \
: [t] "=r" (t) : [a] "r" (x), [b] "r" (y)); \
t; \
})
/* Multiply two S.31 fractional integers, and return the 32 most significant
* bits after a shift left by the constant z. NOTE: Only works for shifts of
* 1 to 8 on Coldfire!
*/
#define FRACMUL_SHL(x, y, z) \
({ \
long t, t2; \
asm ("mac.l %[a], %[b], %%acc0\n\t" \
"moveq.l %[d], %[t]\n\t" \
"move.l %%accext01, %[t2]\n\t" \
"and.l %[mask], %[t2]\n\t" \
"lsr.l %[t], %[t2]\n\t" \
"movclr.l %%acc0, %[t]\n\t" \
"asl.l %[c], %[t]\n\t" \
"or.l %[t2], %[t]\n\t" \
: [t] "=&d" (t), [t2] "=&d" (t2) \
: [a] "r" (x), [b] "r" (y), [mask] "d" (0xff), \
[c] "i" ((z)), [d] "i" (8 - (z))); \
t; \
})
#elif defined(CPU_ARM)
/* Multiply two S.31 fractional integers and return the sign bit and the
* 31 most significant bits of the result.
*/
#define FRACMUL(x, y) \
({ \
long t, t2; \
asm ("smull %[t], %[t2], %[a], %[b]\n\t" \
"mov %[t2], %[t2], asl #1\n\t" \
"orr %[t], %[t2], %[t], lsr #31\n\t" \
: [t] "=&r" (t), [t2] "=&r" (t2) \
: [a] "r" (x), [b] "r" (y)); \
t; \
})
/* Multiply two S.31 fractional integers, and return the 32 most significant
* bits after a shift left by the constant z.
*/
#define FRACMUL_SHL(x, y, z) \
({ \
long t, t2; \
asm ("smull %[t], %[t2], %[a], %[b]\n\t" \
"mov %[t2], %[t2], asl %[c]\n\t" \
"orr %[t], %[t2], %[t], lsr %[d]\n\t" \
: [t] "=&r" (t), [t2] "=&r" (t2) \
: [a] "r" (x), [b] "r" (y), \
[c] "M" ((z) + 1), [d] "M" (31 - (z))); \
t; \
})
#else
#define FRACMUL(x, y) (long) (((((long long) (x)) * ((long long) (y))) >> 31))
#define FRACMUL_SHL(x, y, z) \
((long)(((((long long) (x)) * ((long long) (y))) >> (31 - (z)))))
#endif
/** TAKEN FROM ORIGINAL fixedpoint.h */
/* fast unsigned multiplication (16x16bit->32bit or 32x32bit->32bit,
* whichever is faster for the architecture) */
#ifdef CPU_ARM
#define FMULU(a, b) ((uint32_t) (((uint32_t) (a)) * ((uint32_t) (b))))
#else /* SH1, coldfire */
#define FMULU(a, b) ((uint32_t) (((uint16_t) (a)) * ((uint16_t) (b))))
#endif
long fsincos(unsigned long phase, long *cos);
long fsqrt(long x, unsigned int fracbits);
long sin_int(int val);
long cos_int(int val);
long flog(int x);
/** MODIFIED FROM replaygain.c */
#define FP_INF (0x7fffffff)
#define FP_NEGINF -(0x7fffffff)
/* fracbits in range 12 - 22 work well. Higher is better for
* calculating dB, lower is better for calculating ratio.
*/
long fp_decibels(unsigned long factor, unsigned int fracbits);
long fp_factor(long decibels, unsigned int fracbits);
#endif

2
apps/plugins/lib/SOURCES
View file

@ -1,7 +1,7 @@
gcc-support.c gcc-support.c
jhash.c jhash.c
configfile.c configfile.c
../../fixedpoint.c fixedpoint.c
playback_control.c playback_control.c
rgb_hsv.c rgb_hsv.c
buflib.c buflib.c

238
apps/plugins/lib/fixedpoint.c
View file

@ -0,0 +1,238 @@
/***************************************************************************
* __________ __ ___.
* Open \______ \ ____ ____ | | _\_ |__ _______ ___
* Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ /
* Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < <
* Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \
* \/ \/ \/ \/ \/
* $Id$
*
* Copyright (C) 2006 Jens Arnold
*
* Fixed point library for plugins
*
* 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 software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY
* KIND, either express or implied.
*
****************************************************************************/
#include <inttypes.h>
#include "plugin.h"
#include "fixedpoint.h"
/* Inverse gain of circular cordic rotation in s0.31 format. */
static const long cordic_circular_gain = 0xb2458939; /* 0.607252929 */
/* Table of values of atan(2^-i) in 0.32 format fractions of pi where pi = 0xffffffff / 2 */
static const unsigned long atan_table[] = {
0x1fffffff, /* +0.785398163 (or pi/4) */
0x12e4051d, /* +0.463647609 */
0x09fb385b, /* +0.244978663 */
0x051111d4, /* +0.124354995 */
0x028b0d43, /* +0.062418810 */
0x0145d7e1, /* +0.031239833 */
0x00a2f61e, /* +0.015623729 */
0x00517c55, /* +0.007812341 */
0x0028be53, /* +0.003906230 */
0x00145f2e, /* +0.001953123 */
0x000a2f98, /* +0.000976562 */
0x000517cc, /* +0.000488281 */
0x00028be6, /* +0.000244141 */
0x000145f3, /* +0.000122070 */
0x0000a2f9, /* +0.000061035 */
0x0000517c, /* +0.000030518 */
0x000028be, /* +0.000015259 */
0x0000145f, /* +0.000007629 */
0x00000a2f, /* +0.000003815 */
0x00000517, /* +0.000001907 */
0x0000028b, /* +0.000000954 */
0x00000145, /* +0.000000477 */
0x000000a2, /* +0.000000238 */
0x00000051, /* +0.000000119 */
0x00000028, /* +0.000000060 */
0x00000014, /* +0.000000030 */
0x0000000a, /* +0.000000015 */
0x00000005, /* +0.000000007 */
0x00000002, /* +0.000000004 */
0x00000001, /* +0.000000002 */
0x00000000, /* +0.000000001 */
0x00000000, /* +0.000000000 */
};
/* Precalculated sine and cosine * 16384 (2^14) (fixed point 18.14) */
static const short sin_table[91] =
{
0, 285, 571, 857, 1142, 1427, 1712, 1996, 2280, 2563,
2845, 3126, 3406, 3685, 3963, 4240, 4516, 4790, 5062, 5334,
5603, 5871, 6137, 6401, 6663, 6924, 7182, 7438, 7691, 7943,
8191, 8438, 8682, 8923, 9161, 9397, 9630, 9860, 10086, 10310,
10531, 10748, 10963, 11173, 11381, 11585, 11785, 11982, 12175, 12365,
12550, 12732, 12910, 13084, 13254, 13420, 13582, 13740, 13894, 14043,
14188, 14329, 14466, 14598, 14725, 14848, 14967, 15081, 15190, 15295,
15395, 15491, 15582, 15668, 15749, 15825, 15897, 15964, 16025, 16082,
16135, 16182, 16224, 16261, 16294, 16321, 16344, 16361, 16374, 16381,
16384
};
/**
* Implements sin and cos using CORDIC rotation.
*
* @param phase has range from 0 to 0xffffffff, representing 0 and
* 2*pi respectively.
* @param cos return address for cos
* @return sin of phase, value is a signed value from LONG_MIN to LONG_MAX,
* representing -1 and 1 respectively.
*/
long fsincos(unsigned long phase, long *cos)
{
int32_t x, x1, y, y1;
unsigned long z, z1;
int i;
/* Setup initial vector */
x = cordic_circular_gain;
y = 0;
z = phase;
/* The phase has to be somewhere between 0..pi for this to work right */
if (z < 0xffffffff / 4) {
/* z in first quadrant, z += pi/2 to correct */
x = -x;
z += 0xffffffff / 4;
} else if (z < 3 * (0xffffffff / 4)) {
/* z in third quadrant, z -= pi/2 to correct */
z -= 0xffffffff / 4;
} else {
/* z in fourth quadrant, z -= 3pi/2 to correct */
x = -x;
z -= 3 * (0xffffffff / 4);
}
/* Each iteration adds roughly 1-bit of extra precision */
for (i = 0; i < 31; i++) {
x1 = x >> i;
y1 = y >> i;
z1 = atan_table[i];
/* Decided which direction to rotate vector. Pivot point is pi/2 */
if (z >= 0xffffffff / 4) {
x -= y1;
y += x1;
z -= z1;
} else {
x += y1;
y -= x1;
z += z1;
}
}
if (cos)
*cos = x;
return y;
}
/**
* Fixed point square root via Newton-Raphson.
* @param a square root argument.
* @param fracbits specifies number of fractional bits in argument.
* @return Square root of argument in same fixed point format as input.
*/
long fsqrt(long a, unsigned int fracbits)
{
long b = a/2 + BIT_N(fracbits); /* initial approximation */
unsigned n;
const unsigned iterations = 4;
for (n = 0; n < iterations; ++n)
b = (b + (long)(((long long)(a) << fracbits)/b))/2;
return b;
}
/**
* Fixed point sinus using a lookup table
* don't forget to divide the result by 16384 to get the actual sinus value
* @param val sinus argument in degree
* @return sin(val)*16384
*/
long sin_int(int val)
{
val = (val+360)%360;
if (val < 181)
{
if (val < 91)/* phase 0-90 degree */
return (long)sin_table[val];
else/* phase 91-180 degree */
return (long)sin_table[180-val];
}
else
{
if (val < 271)/* phase 181-270 degree */
return -(long)sin_table[val-180];
else/* phase 270-359 degree */
return -(long)sin_table[360-val];
}
return 0;
}
/**
* Fixed point cosinus using a lookup table
* don't forget to divide the result by 16384 to get the actual cosinus value
* @param val sinus argument in degree
* @return cos(val)*16384
*/
long cos_int(int val)
{
val = (val+360)%360;
if (val < 181)
{
if (val < 91)/* phase 0-90 degree */
return (long)sin_table[90-val];
else/* phase 91-180 degree */
return -(long)sin_table[val-90];
}
else
{
if (val < 271)/* phase 181-270 degree */
return -(long)sin_table[270-val];
else/* phase 270-359 degree */
return (long)sin_table[val-270];
}
return 0;
}
/**
* Fixed-point natural log
* taken from http://www.quinapalus.com/efunc.html
* "The code assumes integers are at least 32 bits long. The (positive)
* argument and the result of the function are both expressed as fixed-point
* values with 16 fractional bits, although intermediates are kept with 28
* bits of precision to avoid loss of accuracy during shifts."
*/
long flog(int x) {
long t,y;
y=0xa65af;
if(x<0x00008000) x<<=16, y-=0xb1721;
if(x<0x00800000) x<<= 8, y-=0x58b91;
if(x<0x08000000) x<<= 4, y-=0x2c5c8;
if(x<0x20000000) x<<= 2, y-=0x162e4;
if(x<0x40000000) x<<= 1, y-=0x0b172;
t=x+(x>>1); if((t&0x80000000)==0) x=t,y-=0x067cd;
t=x+(x>>2); if((t&0x80000000)==0) x=t,y-=0x03920;
t=x+(x>>3); if((t&0x80000000)==0) x=t,y-=0x01e27;
t=x+(x>>4); if((t&0x80000000)==0) x=t,y-=0x00f85;
t=x+(x>>5); if((t&0x80000000)==0) x=t,y-=0x007e1;
t=x+(x>>6); if((t&0x80000000)==0) x=t,y-=0x003f8;
t=x+(x>>7); if((t&0x80000000)==0) x=t,y-=0x001fe;
x=0x80000000-x;
y-=x>>15;
return y;
}

181
apps/replaygain.c
View file

@ -30,11 +30,188 @@
#include "metadata.h" #include "metadata.h"
#include "debug.h" #include "debug.h"
#include "replaygain.h" #include "replaygain.h"
#include "fixedpoint.h"
/* The fixed point math routines (with the exception of fp_atof) are based
* on oMathFP by Dan Carter (http://orbisstudios.com).
*/
/* 12 bits of precision gives fairly accurate result, but still allows a
* compact implementation. The math code supports up to 13...
*/
#define FP_BITS (12) #define FP_BITS (12)
#define FP_MASK ((1 << FP_BITS) - 1)
#define FP_ONE (1 << FP_BITS) #define FP_ONE (1 << FP_BITS)
#define FP_TWO (2 << FP_BITS)
#define FP_HALF (1 << (FP_BITS - 1))
#define FP_LN2 ( 45426 >> (16 - FP_BITS))
#define FP_LN2_INV ( 94548 >> (16 - FP_BITS))
#define FP_EXP_ZERO ( 10922 >> (16 - FP_BITS))
#define FP_EXP_ONE ( -182 >> (16 - FP_BITS))
#define FP_EXP_TWO ( 4 >> (16 - FP_BITS))
#define FP_INF (0x7fffffff)
#define FP_LN10 (150902 >> (16 - FP_BITS))
#define FP_MAX_DIGITS (4)
#define FP_MAX_DIGITS_INT (10000)
#define FP_FAST_MUL_DIV
#ifdef FP_FAST_MUL_DIV
/* These macros can easily overflow, but they are good enough for our uses,
* and saves some code.
*/
#define fp_mul(x, y) (((x) * (y)) >> FP_BITS)
#define fp_div(x, y) (((x) << FP_BITS) / (y))
#else
static long fp_mul(long x, long y)
{
long x_neg = 0;
long y_neg = 0;
long rc;
if ((x == 0) || (y == 0))
{
return 0;
}
if (x < 0)
{
x_neg = 1;
x = -x;
}
if (y < 0)
{
y_neg = 1;
y = -y;
}
rc = (((x >> FP_BITS) * (y >> FP_BITS)) << FP_BITS)
+ (((x & FP_MASK) * (y & FP_MASK)) >> FP_BITS)
+ ((x & FP_MASK) * (y >> FP_BITS))
+ ((x >> FP_BITS) * (y & FP_MASK));
if ((x_neg ^ y_neg) == 1)
{
rc = -rc;
}
return rc;
}
static long fp_div(long x, long y)
{
long x_neg = 0;
long y_neg = 0;
long shifty;
long rc;
int msb = 0;
int lsb = 0;
if (x == 0)
{
return 0;
}
if (y == 0)
{
return (x < 0) ? -FP_INF : FP_INF;
}
if (x < 0)
{
x_neg = 1;
x = -x;
}
if (y < 0)
{
y_neg = 1;
y = -y;
}
while ((x & BIT_N(30 - msb)) == 0)
{
msb++;
}
while ((y & BIT_N(lsb)) == 0)
{
lsb++;
}
shifty = FP_BITS - (msb + lsb);
rc = ((x << msb) / (y >> lsb));
if (shifty > 0)
{
rc <<= shifty;
}
else
{
rc >>= -shifty;
}
if ((x_neg ^ y_neg) == 1)
{
rc = -rc;
}
return rc;
}
#endif /* FP_FAST_MUL_DIV */
static long fp_exp(long x)
{
long k;
long z;
long R;
long xp;
if (x == 0)
{
return FP_ONE;
}
k = (fp_mul(abs(x), FP_LN2_INV) + FP_HALF) & ~FP_MASK;
if (x < 0)
{
k = -k;
}
x -= fp_mul(k, FP_LN2);
z = fp_mul(x, x);
R = FP_TWO + fp_mul(z, FP_EXP_ZERO + fp_mul(z, FP_EXP_ONE
+ fp_mul(z, FP_EXP_TWO)));
xp = FP_ONE + fp_div(fp_mul(FP_TWO, x), R - x);
if (k < 0)
{
k = FP_ONE >> (-k >> FP_BITS);
}
else
{
k = FP_ONE << (k >> FP_BITS);
}
return fp_mul(k, xp);
}
static long fp_exp10(long x)
{
if (x == 0)
{
return FP_ONE;
}
return fp_exp(fp_mul(FP_LN10, x));
}
static long fp_atof(const char* s, int precision) static long fp_atof(const char* s, int precision)
{ {
@ -123,7 +300,7 @@ static long convert_gain(long gain)
gain = 17 * FP_ONE; gain = 17 * FP_ONE;
} }
gain = fp_factor(gain, FP_BITS) << (24 - FP_BITS); gain = fp_exp10(gain / 20) << (24 - FP_BITS);
return gain; return gain;
} }